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Xyelm differentiation

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Parul Sharma
Parul Sharma

The document summarizes vascular tissue differentiation and xylem cell differentiation. It discusses: 1) Procambial cells give rise to vascular tissues through de novo differentiation or cell division. Auxin and transcription factors like MONOPTEROS and PINFORMED1 regulate vascular tissue formation. 2) Xylem cells differentiate through secondary cell wall formation and programmed cell death. Transcription factors like VND6, VND7 and SND1 regulate these processes. 3) KANADI/HD-ZIP/miRNA165/166 balance radial patterning by restricting auxin flow. The WOX4/PXY/CLE41 signaling module regulates cambial cell proliferation and inhibits xyle

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XYLEM DIFFRENTIATION PARUL SHARMA PHD BOTANY
Vascular tissue differentiation - The mature vascular tissues consists of highly specialised cell types that generally arise from discrete populations of undifferentiated progenitor cells located in the meristems niches. The root and shoot apical meristem are established during embryo development whereas the lateral meristem that constitutes procambium and vascular cambium appear at later stages of development and result from re differentiation process. The procambial cells are the precursor of vascular tissue. The procambial cells can arise through the de-novo differentiation of parenchyma cells in a process that not only commit each recruited cell to a vascular cell fate but also generates adjoined files of such cells. The parenchymal cells that are committed to become vascular tissue can be easily distinguished from the other ground tissue cells. The ground tissue cells are isodiametric in shape whereas the
Once formed, the individual pro cambial cells can undergo paraclinical divisions and ultimately give rise to procambium tissue from which specialised xylem and phloem cells are formed. Some cells within the pro cambion remains in an undifferentiated state and are positioned between the differentiating xylem and phloem tissue. These cells functions as vascular stem cells and enable the prolonged formation of vascular tissues in rapidly elongating or expanding organs such as young stems and leaves during primary growth. In woody plants, where a pattern of secondary growth occurs, specialized stem cells arise from procambium to form vascular cambium, a lateral metistem from which extensive secondary xylem (wood) is formed. In Arabidopsis thaliana, although no extensive secondary growth occurs, two regions of vascular cambium—zones of fascicular cambium and the neighboring zones of interfascicular cambium—are found within the Arabidopsis inflorescence stem. Despite their proximity to each other and their apparent similarity, these two cambial niches have different
The fascicular cambium is derived from the procambium that developed within the original vascular tissue as it was formed during the primary growth of the stem. The interfascicular cambium, on the other hand, is thought to arise through the de novo recruitment of interfascicular parenchyma cells as primary growth in the stem slows. It represents a specialized vascular meristem that gives rise exclusively to the structurally important interfascicular fibres. Thus, the procambium provides a source of vascular stem cells during primary growth while the vascular cambium performs an analogous role during secondary growth as the plant continue to grow and mature.
Overview of procambial/cambial cell specification and xylem/phloem cell differentiation. Procambial cells can form by the de novo differentiation of parenchyma cells, or by division of existing procambial cells during primary growth, thereby forming the procambium. The vascular cambium and associated cambial cells are derived from the procambium during the transition to secondary growth, at which point the nomenclature of ‘procambial’ cells no longer applies and ‘cambial’ cells is used instead. In woody plants, the cambial cells are further categorized as ray initials or fusiform initials (not shown here). Cambial/procambial cells differentiate into either xylem or phloem cell types.
XYLEM TISSUE - The pro cambial cell give rise to to xylem precursor which than differentiates to to various cell types of xylem and phloem. Mature xylem tissue composed of various types of cells : xylem tracheary ( vessel) elements, xylary fibres, and xylem parenchyma cells. Tracheary elements, facilitate water and solute transport between organs and possess thick secondary cell walls. The elements formed during early and later stages of plant and vascular development are structurally distinguished as protoxylem and metaxylem. Protoxylem elements form during primary plant growth and have helical secondary cell wall thickening that allowed the cells to continue to elongate within actively growing areas of a plant. A relatively larger metaxylem elements are formed when the vascular tissues mature and the primary glow growths ceases. They have reticulate pattern of secondary cell wall deposition that does not allow continuous cell elongation. As a final stage of differentiation, both protoxylem and metaxylem tracheary elements
Undergo programmed cell death (PCD), Resulting in a continuous system of Adjoining hollow cells that function in Water/solute transport. Xylem parenchyma cells lack well-defined Secondary cell walls and are implicated In a variety of biological processes, including Aiding the lignification of secondary cell Walls in neighbouring vessel elements And fibres. Xylem fibres consist of thick and evenly Deposited secondary cell wall in contrast To patterned deposition of secondary cell Wall in xylem tracheary elements. During the development of fibres PCD is delayed allowing for more extensive thickening and lignification of secondary cell walls that plays an important role in providing structural support.
Triggering of vascular tissue for differentiation - The parenchymatous cells are converted to procambial precursors. Early experiments established that ectopic application of the hormone auxin [indole-3-acetic acid (IAA)] was sufficient to trigger the specification of vascular tissue, including proliferation of cambial cells and final differentiation of vascular cell types. Sachs (1981) proposed the ‘canalization of auxin flow hypothesis’ as a model for the auxin-mediated formation of vascular tissues. In this model, channels of preferential auxin flow are created when a series of cells gradually become specialized for directional auxin transport. Once established, these channels effectively drain auxin from surrounding cells, resulting in localized concentration of auxin within distinct cell files, and this shift in auxin distribution was hypothesized to subsequently induce vascular tissue formation. Both cytokinin and auxin are required for efficient trans-differentiation of mesophyll cells in in vitro tracheary element (xylem vessel) differentiation
A number of genes are identified that are involved in auxin signalling and transport. For example, the MONOPTEROS (MP) gene is a member of a transcription factor gene family encoding auxin response factor (ARF) proteins, which are involved in regulating auxin responsive gene expression. Loss of function of mp mutants have pleiotropic phenotypes, including a highly reduced leaf vein system and mis aligned tracheary elements in arabidopsis inflorescence stems and leaves. PINFORMED1 (PIN1) gene that encodes a plasma membrane-localized auxin efflux protein. Asymmetric localization of PIN1 in plant cells is thought to establish a directional auxin flow. Mp mutants have severely attenuated levels of expression of the PIN1 gene. In the arabidopsis leaf, PIN1 and MP are coexpressed during very early stages of procambial cell specification, and their spatial pattern of expression gradually changes from initially broader domains to a single file of cells, as predicted for positive feedback onto the auxin canalization process. Athb8, a member of the class III homeodomain leucine zipper (HD-ZIP) transcription factor family, is co-expressed with MP and PIN1 during vascular
The radial patterning of vascular tissue - Despite the apparent uniformity of the stem cell population within each cambial niche (procambium and vascular cambium), differentiation programmes occurring in precursor cells simultaneously convert some of them into either xylem or phloem cell types. Phloem typically forms at the face of the cambial cell population oriented toward the abaxial ( lower) surface of the leaf, and at the outwardfacing surface of the stem, whereas xylem forms in the adaxial (upper) and inward-facing position in leaves and stems, respectively. As a result, vascular differentiation results in a tissue organization pattern in which xylem, cambium, and phloem occupy specific radial positions within developing organs and stems. The shoot-to- root polar auxin transport occurs in the cells associated with the procambium and vascular cambium, and that auxin levels peak along the radial axis within cambial and differentiating xylem cells. Gene families such as KANADI and class III HD-ZIP are important regulators of the overall abaxial/ adaxial polarity of all shoot lateral organs, as well as the radial
Cross-section of the fascicular cambium region of an arabidopsis inflorescence stem showing the epidermis and cortex in green, phloem tissue in blue, vascular cambium in khaki, xylem tissue in yellow, and pith cells in pale blue. In this model, phloem-expressed KANADI (KAN) genes restrict PAT to the cambium and developing xylem regions, while HD-ZIP genes positively influence PAT and promote xylem development. The expression domains of HD-ZIP genes are maintained by auxin and by post-transcriptional gene silencing mediated by phloem-expressed
The KANADI/HD-ZIP/mirna165/166 nexus - ● The four KANADI genes (KAN1,2,3,4) are expressed in abaxial domains of developing shoot lateral organs, as well as in phloem tissues throughout the plant. ● On the other hand, five class iii hd-zip transcription factors (athb15/corona, phabulosa, phavoluta, revoluta/interfascicular fibreless, and athb8) are expressed in complementary domains, and function to specify adaxial cell fate of shoot lateral organs, in addition to promoting meristem function and xylem tissue formation.
● Quadruple mutants of the KAN1, 2, 3, and 4 genes produce a amphivasal (xylem surrounding phloem) radial pattern of vascular tissue organization and kan loss of function has been correlated with the expansion of HD-ZIP gene expression domains. ● Triple loss-of-function mutants of the hd-zip genes, revoluta, phabulosa, and phavoluta, possess an amphicribal (phloem surrounding xylem) radial pattern that correspond to an expansion of kan gene expression domains. ● Kan genes inhibit pin gene expression in abaxial phloem-forming tissues, thereby negatively regulating canalization of auxin flow and
● HD-ZIP genes positively regulate canalization of auxin by activating the expression of genes that promote auxin transport (PINs and ARFs) and thus promote procambium/cambium formation. The expression of HD-ZIP genes is, in turn, activated by auxin, thus completing a positive feedback cycle. ● The phloem-expressed miRNAs further define HD-ZIP gene expression domains by limiting HD-ZIP transcript stability in the phloem-forming regions of the procambium/cambium. The expression domains of miRNAs 165 and 166 overlap considerably with those of KAN genes in Arabidopsis phloem tissues and abaxial leaf domains, and these miRNAs can directly regulate HD-ZIP function. Thus, overexpression of miRNA 165 or 166 leads to enhanced degradation of HD-ZIP transcripts, thereby phenocopying HD-ZIP loss-of-function mutants.
The WOX/PXY/CLE41/44 signalling module - ● A diffusion gradient of peptide signaling molecules originating from differentiating phloem cells acts as key regulator of vascular cambium function and patterning. The three cle genes (cle41, 42, and 44) that possess tdif activity (cle/tdif) are expressed and processed into peptide signalling molecules in phloem cells, and the resulting peptides subsequently diffuse into the apoplast to reach neighbouring cells. CLE41, CLE42, and CLE44 are the members of the CLAVATA3/EMBRYO SURROUNDING region-related (CLE) gene family, they encode proteins that are post-translationally processed to form 12-amino acid signalling peptides. These peptides were initially identified as ‘tracheary element differentiation inhibitory factors’ (tdifs). ● Phloem intercalated with xylem/tdif receptor (pxy/tdr), is the product of leucine-rich repeat receptor- like kinase (lrr-rlk) gene, acts as a functional receptor for cle/tdif peptides. The spatial arrangement of CLE/TDIF peptide production in phloem cells, and of PXY/TDR receptor expression in
CLE/TDIF peptides (red spheres) originating from phloem cell types diffuse throughout the apoplast and are sequestered by the PXY/ TDR receptor (green rectangles) which is specifically expressed in cambial cells. The polar activation of PXY/TDR signalling leads to cambial cell polarization and results in periclinal division. PXY/TDR signalling also promotes wox4-mediated cambial cell proliferation and promotes stem cell fate by inhibiting xylem differentiation.
● CLE/ TDIF peptide signalling through the PXY/TDR receptor stimulates procambial/cambial cell proliferation and inhibits xylem differentiation. ● The expression of the wox4 (wuschel-related homeobox) transcription factor is up regulated due to pxy/tdr signal transduction. WOX4 is specifically expressed in the procambium/cambium stem cell niche where it functions to stimulate cell proliferation.
Differentiation of xylem cell types - The two main steps in the maturation of xylem tracheary elements are secondary cell wall formation and PCD (programmed cell death). A network of transcription factors that regulate the expression of numerous genes are identified that are directly involved in the biosynthesis of secondary cell walls and in PCD. The ‘master regulator’ genes are thought to be positioned near the top of transcriptional cascades that control the xylem differentiation process and direct it to specific end points. ● Initiation of tracheary element differentiation - Vnd7 and vnd6 belong to a seven-member gene family encoding vnd (vascular-related nac domain) transcription factors whose expression led to tracheary element differentiation. Expression of VND7 and VND6 is specifically localized to developing protoxylem and metaxylem respectively. The
Programme places these genes at, or near the top of, the transcriptional cascade regulating xylem tracheary element differentiation. Vni2 (vnd-interacting 2) is a transcriptional repressor protein that binds to vnd proteins and inhibit vnd7- mediated gene transcription. The VNI2 protein is targeted for degradation when VND7 expression is required for protoxylem tracheary element differentiation.
● Initiation of fibre differentiation - The expression of nac domain containing transcription factor snd1 is sufficient to differentiate non vascular cell types into fibre like cells. Like VND6 and VND7, SND1 regulates a transcriptional cascade that ultimately activates the specific genes necessary for secondary cell wall biosynthesis. The ectopic overexpression of snd1 results in uniform deposition of secondary cell walls in contrast to the helical or pitted secondary cell walls observed in protoxylem and metaxylem tracheary elements. SND1 functions redundantly with two other NAC transcription factors, NST1 and NST2, to control secondary cell wall formation of all fibre types in Arabidopsis. Single loss-of-function mutants of snd1 or nst1 have no observable phenotype, but developing fibres in the snd1nst1 double mutant retain the general fibre cell shape but have no secondary cell walls. Vnd6, vnd7, and snd1 share significant functional overlap in their ability to activate the downstream transcriptional network and the general metabolic machinery required to form secondary cell walls.
The secondary cell wall transcription network converges on MYB46 and MYB83 - ● the secondary cell wall NAC domain transcription factors (VND6,VND7, SND1, NST1 and NST2) binds to SNBE (secondary wall NAC binding element) regulatory regions in the promoter of target genes and activates transcriptional network for secondary cell wall formation. ● The promoters of myb46 and myb83 contain several snbe promoter elements and direct targets of secondary cell wall genes. Double myb46 myb83 knockout mutants are defective in secondary cell wall formation. In ‘seedling lethal’ phenotype of myb46 myb83 plants, vascular tissue formation is completely abolished or the integrity of secondary cell walls is severely compromised. ● The master switch, snd1, activates the expression of myb46 and myb83, along with other genes, including snd3, myb103, and knat7 (which do not appear to make as prominent a contribution to the extension of the network).
● Dominant negative repression of each of these downstream genes resulted in reduced secondary cell wall thickening of both interfascicular fibres and xylary fibres, but not in tracheary elements. ● Snd2, snd3, and myb103 constructs were able to activate the promoters for genes involved in cellulose biosynthesis. ● Myb52 and myb54 constructs activated promoters for genes involved in cellulose, xylan, and lignin biosynthesis, (indicative of a more general role for these two mybs in regulation of cell wall biosynthetic enzymes). ● Myb46 and/or myb83 influence the expression of four transcription factors (knat7, myb4, myb7, and myb32) that function as transcriptional repressors. They repress the expression of master switches such as SND1 and also directly or indirectly repress the expression of genes involved in secondary cell wall biosynthesis. ● Knat7 works as both a positive and negative regulator of different genes involved in secondary cell wall biosynthesis.
● In the absence of KNAT7 function, the expression of two secondary cell wall cellulose synthase genes, a number of hemicellulose biosynthesis genes and the majority of lignin biosynthesis genes is increased. In arabidopsis, the overexpression of KNAT7 led to thinner secondary cell wall phenotypes which shows that it acts as a negative regulator of secondary cell wall deposition. ● Myb46 activates the expression of the myb4, myb7, and myb32 genes. These function as potent transcriptional repressors. MYB4 and MYB32 also function to repress lignin biosynthesis, with MYB32 negatively regulating general phenylpropanoid biosynthesis genes and MYB4 specifically suppressing the expression of the C4H gene, which encodes the first committed step in the phenylpropanoid pathway.
Cellulosic secondary cell wall - The secondary cell walls of flowering plants is predominantly composed of cellulose accompanied by lesser amounts of hemicellulose and lignin. Most of the genes involved in the biosynthesis of each of the three main components have been identified. The lignification of the secondary cell wall generally occur after the initial deposition of the cellulosic components that is initiated in a spatially distinct manner. There lies significant parallels between primary and secondary cell wall cellulose synthesis. In both cases, cellulose synthesis complexes (cscs) composed of 36 cesa (cellulose synthesis A) isoform subunits catalyse the linear polymerization of glucose molecules. Distinct subgroups of cesa genes appear to be involved in cellulose biosynthesis in primary or in secondary cell walls. In arabidopsis, the products of the cesa4, cesa7, and cesa8 genes
The length of individual cellulose chains ranges from 500 to 2000 glucose molecules in primary cell walls, but can extend to >10 000 glucose molecules in secondary cell walls. A high density of cscs have been localized to specific plasma membrane domains immediately below that developing secondary walls. In Arabidopsis root protoxylem, microtubule bundles oriented along the borders of the developing secondary cell wall thickening helped to organize functional cscs at particular regions of the plasma membrane. Hemicellulose are branched cell wall matrix polysaccharides composed of glucose mannose or xylose. They are synthesized in the Golgi and the hemicellulose containing vesicles are trafficked to specific plasma membrane domains during secondary cell wall formation. Glucuronoxylan is the most abundant hemicellulose found in the secondary cell walls of dicotyledonous plants and is thought to function as the major cellulose crosslinking component in secondary cell walls.
Lignification and programmed cell death - The cellulosic secondary cell wall undergoes lignification in tracheary elements and fibers. Lignin imparts both increased structural stability and water impermeability to the cell wall. The failure of lignin biosynthesis leads to irregular xylem (IRX) phenotypes. The process of lignification is tightly controlled both temporally and spatially. In protoxylem, the lignin polymerization is restricted to narrow helical or annular zones of secondary cell wall deposition and in metaxylem it occurs in reticulate pattern.
The lignin biosynthesis pathway can be divided into two parts. The first is the general phenylpropanoid pathway, a multistep reaction sequence that generates precursors not only for synthesis of lignin monomers (monolignol alcohols), but also for the synthesis of other phenylpropanoid compounds such as flavonoids, tannins, phenolic esters, and acids. The second pathway is more specific monolignol biosynthetic pathway that provides substrates for the enzymes encoded by members of the ccr, comt, f5h, and cad gene families. The metabolic reactions required for monolignol biosynthesis are believed to operate in the cytosol, or perhaps in the region of the cytosol directly associated with the endoplasmic reticulum. In order for monolignols to participate in polymerization to form the final lignin structure, they must move from their site of synthesis, across the plasma membrane to the cell wall. They potentially exit the cell by passive diffusion. In arabidopsis, several abc transporters facilitate the export of a wide range of low molecular weight, hydrophobic substrates, including auxin, it is possible
A set of candidate ABC transporters for monolignol export was previously identified based on their co-expression with phenylpropanoid biosynthesis genes in developing arabidopsis inflorescence stems. Lignin polymerization - The oxidation of the monolignol molecule is catalysed by one or more peroxidases and/or laccases, and the resulting radical is then coupled with a phenoxy radical on the growing lignin chain, through a process referred to as endwise polymerization. The laccases LAC4 and LAC17 are necessary for normal lignification of Arabidopsis fiber cell walls and, to some extent, of tracheary elements. Expression of the LAC4 gene was also found to be up- regulated in response to overexpression of the MYB58 transcription factor. Lignin is synthesized by dehydrogenative polymerization of phenyl propanoid units, namely, coniferyl alcohol, sinapyl alcohol and coumaryl alcohol, which corresponds to guaiacyl (G), syringyl (S) and p-hydroxyphenyl (H) structures of lignin, respectively.
In Arabidopsis, tracheary elements have secondary cell walls composed primarily of g-lignin while the walls of the interfascicular fibers are s- lignin rich. In Arabidopsis, tracheary elements have secondary cell walls composed primarily of g-lignin while the walls of the interfascicular fibers are s- lignin rich. The first stage of lignification during xylem development involves the incorporation of a mixture of h-lignin (dominated by 4-hydroxy ring structures) and g-lignin in the middle lamella and cell corners. In the next phase of wall lignification, the primary cell wall and outer layers of the secondary cell wall are lignified primarily with g-lignin. The last stage of lignin deposition is directed to the innermost layer of the secondary cell wall, and in fibers it is largely s-lignin that is formed at this stage.
Programmed cell death - During fibre development, the thick secondary cell wall is formed over an extended period, whereas tracheary element differentiation progresses quickly from secondary cell wall deposition to pcd. The expression of several genes functionally associated with PCD is correlated with xylem development. Some genes [e.G. XYLEM CYSTEINE PROTEASE1 and 2 (XCP1 and XCP2); BIFUNCTIONAL NUCLEASE1 (BFN1)] have also been shown to be directly activated by both the VND7 and VND6 transcription factors. Cysteine protease plays a role in executing pcd. In gene transcript profiling in the zinnia tracheary element differentiation cell culture system, the large central vacuole of the nascent tracheary element cell plays a critical role in pcd. Modifications or disruptions of the tonoplast (vacuolar membrane), and accompanying changes in the vacuolar contents, define the initial stage of PCD.
The subsequent rupture of the vacuole and release of digestive enzymes such as nucleases and proteases results in digestion of all the cell contents, leaving only the cell wall intact. A study in Poplar has confirmed that tracheary elements undergo PCD and associated vacuolar collapse much earlier than do fibres. In tracheary elements, vacuolar collapse marks the PCD, while PCD in fibres starts with DNA degradation and cellular dismantling. Tracheary element PCD occurs rapidly, with the vacuolar implosion requiring only a few minutes, and the clearance of the remainder of the cell contents is completed within a few hours whereas fibre PCD takes much longer. The non-cell-autonomous lignification model suggests that non-lignifying cells such as xylary parenchyma cells, positioned adjacent to lignifying cells such as tracheary elements, are capable of synthesizing monolignols and exporting them to the cell wall of the neighbouring lignifying cells. In Zinnia cell cultures, these parenchyma-like cells may act as ‘good neighbours’ for the differentiating tracheary elements and provide them with

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Xyelm differentiation

  • 2. Vascular tissue differentiation - The mature vascular tissues consists of highly specialised cell types that generally arise from discrete populations of undifferentiated progenitor cells located in the meristems niches. The root and shoot apical meristem are established during embryo development whereas the lateral meristem that constitutes procambium and vascular cambium appear at later stages of development and result from re differentiation process. The procambial cells are the precursor of vascular tissue. The procambial cells can arise through the de-novo differentiation of parenchyma cells in a process that not only commit each recruited cell to a vascular cell fate but also generates adjoined files of such cells. The parenchymal cells that are committed to become vascular tissue can be easily distinguished from the other ground tissue cells. The ground tissue cells are isodiametric in shape whereas the
  • 3. Once formed, the individual pro cambial cells can undergo paraclinical divisions and ultimately give rise to procambium tissue from which specialised xylem and phloem cells are formed. Some cells within the pro cambion remains in an undifferentiated state and are positioned between the differentiating xylem and phloem tissue. These cells functions as vascular stem cells and enable the prolonged formation of vascular tissues in rapidly elongating or expanding organs such as young stems and leaves during primary growth. In woody plants, where a pattern of secondary growth occurs, specialized stem cells arise from procambium to form vascular cambium, a lateral metistem from which extensive secondary xylem (wood) is formed. In Arabidopsis thaliana, although no extensive secondary growth occurs, two regions of vascular cambium—zones of fascicular cambium and the neighboring zones of interfascicular cambium—are found within the Arabidopsis inflorescence stem. Despite their proximity to each other and their apparent similarity, these two cambial niches have different
  • 4. The fascicular cambium is derived from the procambium that developed within the original vascular tissue as it was formed during the primary growth of the stem. The interfascicular cambium, on the other hand, is thought to arise through the de novo recruitment of interfascicular parenchyma cells as primary growth in the stem slows. It represents a specialized vascular meristem that gives rise exclusively to the structurally important interfascicular fibres. Thus, the procambium provides a source of vascular stem cells during primary growth while the vascular cambium performs an analogous role during secondary growth as the plant continue to grow and mature.
  • 5. Overview of procambial/cambial cell specification and xylem/phloem cell differentiation. Procambial cells can form by the de novo differentiation of parenchyma cells, or by division of existing procambial cells during primary growth, thereby forming the procambium. The vascular cambium and associated cambial cells are derived from the procambium during the transition to secondary growth, at which point the nomenclature of ‘procambial’ cells no longer applies and ‘cambial’ cells is used instead. In woody plants, the cambial cells are further categorized as ray initials or fusiform initials (not shown here). Cambial/procambial cells differentiate into either xylem or phloem cell types.
  • 6. XYLEM TISSUE - The pro cambial cell give rise to to xylem precursor which than differentiates to to various cell types of xylem and phloem. Mature xylem tissue composed of various types of cells : xylem tracheary ( vessel) elements, xylary fibres, and xylem parenchyma cells. Tracheary elements, facilitate water and solute transport between organs and possess thick secondary cell walls. The elements formed during early and later stages of plant and vascular development are structurally distinguished as protoxylem and metaxylem. Protoxylem elements form during primary plant growth and have helical secondary cell wall thickening that allowed the cells to continue to elongate within actively growing areas of a plant. A relatively larger metaxylem elements are formed when the vascular tissues mature and the primary glow growths ceases. They have reticulate pattern of secondary cell wall deposition that does not allow continuous cell elongation. As a final stage of differentiation, both protoxylem and metaxylem tracheary elements
  • 7. Undergo programmed cell death (PCD), Resulting in a continuous system of Adjoining hollow cells that function in Water/solute transport. Xylem parenchyma cells lack well-defined Secondary cell walls and are implicated In a variety of biological processes, including Aiding the lignification of secondary cell Walls in neighbouring vessel elements And fibres. Xylem fibres consist of thick and evenly Deposited secondary cell wall in contrast To patterned deposition of secondary cell Wall in xylem tracheary elements. During the development of fibres PCD is delayed allowing for more extensive thickening and lignification of secondary cell walls that plays an important role in providing structural support.
  • 8. Triggering of vascular tissue for differentiation - The parenchymatous cells are converted to procambial precursors. Early experiments established that ectopic application of the hormone auxin [indole-3-acetic acid (IAA)] was sufficient to trigger the specification of vascular tissue, including proliferation of cambial cells and final differentiation of vascular cell types. Sachs (1981) proposed the ‘canalization of auxin flow hypothesis’ as a model for the auxin-mediated formation of vascular tissues. In this model, channels of preferential auxin flow are created when a series of cells gradually become specialized for directional auxin transport. Once established, these channels effectively drain auxin from surrounding cells, resulting in localized concentration of auxin within distinct cell files, and this shift in auxin distribution was hypothesized to subsequently induce vascular tissue formation. Both cytokinin and auxin are required for efficient trans-differentiation of mesophyll cells in in vitro tracheary element (xylem vessel) differentiation
  • 9. A number of genes are identified that are involved in auxin signalling and transport. For example, the MONOPTEROS (MP) gene is a member of a transcription factor gene family encoding auxin response factor (ARF) proteins, which are involved in regulating auxin responsive gene expression. Loss of function of mp mutants have pleiotropic phenotypes, including a highly reduced leaf vein system and mis aligned tracheary elements in arabidopsis inflorescence stems and leaves. PINFORMED1 (PIN1) gene that encodes a plasma membrane-localized auxin efflux protein. Asymmetric localization of PIN1 in plant cells is thought to establish a directional auxin flow. Mp mutants have severely attenuated levels of expression of the PIN1 gene. In the arabidopsis leaf, PIN1 and MP are coexpressed during very early stages of procambial cell specification, and their spatial pattern of expression gradually changes from initially broader domains to a single file of cells, as predicted for positive feedback onto the auxin canalization process. Athb8, a member of the class III homeodomain leucine zipper (HD-ZIP) transcription factor family, is co-expressed with MP and PIN1 during vascular
  • 10. The radial patterning of vascular tissue - Despite the apparent uniformity of the stem cell population within each cambial niche (procambium and vascular cambium), differentiation programmes occurring in precursor cells simultaneously convert some of them into either xylem or phloem cell types. Phloem typically forms at the face of the cambial cell population oriented toward the abaxial ( lower) surface of the leaf, and at the outwardfacing surface of the stem, whereas xylem forms in the adaxial (upper) and inward-facing position in leaves and stems, respectively. As a result, vascular differentiation results in a tissue organization pattern in which xylem, cambium, and phloem occupy specific radial positions within developing organs and stems. The shoot-to- root polar auxin transport occurs in the cells associated with the procambium and vascular cambium, and that auxin levels peak along the radial axis within cambial and differentiating xylem cells. Gene families such as KANADI and class III HD-ZIP are important regulators of the overall abaxial/ adaxial polarity of all shoot lateral organs, as well as the radial
  • 11. Cross-section of the fascicular cambium region of an arabidopsis inflorescence stem showing the epidermis and cortex in green, phloem tissue in blue, vascular cambium in khaki, xylem tissue in yellow, and pith cells in pale blue. In this model, phloem-expressed KANADI (KAN) genes restrict PAT to the cambium and developing xylem regions, while HD-ZIP genes positively influence PAT and promote xylem development. The expression domains of HD-ZIP genes are maintained by auxin and by post-transcriptional gene silencing mediated by phloem-expressed
  • 12. The KANADI/HD-ZIP/mirna165/166 nexus - ● The four KANADI genes (KAN1,2,3,4) are expressed in abaxial domains of developing shoot lateral organs, as well as in phloem tissues throughout the plant. ● On the other hand, five class iii hd-zip transcription factors (athb15/corona, phabulosa, phavoluta, revoluta/interfascicular fibreless, and athb8) are expressed in complementary domains, and function to specify adaxial cell fate of shoot lateral organs, in addition to promoting meristem function and xylem tissue formation.
  • 13. ● Quadruple mutants of the KAN1, 2, 3, and 4 genes produce a amphivasal (xylem surrounding phloem) radial pattern of vascular tissue organization and kan loss of function has been correlated with the expansion of HD-ZIP gene expression domains. ● Triple loss-of-function mutants of the hd-zip genes, revoluta, phabulosa, and phavoluta, possess an amphicribal (phloem surrounding xylem) radial pattern that correspond to an expansion of kan gene expression domains. ● Kan genes inhibit pin gene expression in abaxial phloem-forming tissues, thereby negatively regulating canalization of auxin flow and
  • 14. ● HD-ZIP genes positively regulate canalization of auxin by activating the expression of genes that promote auxin transport (PINs and ARFs) and thus promote procambium/cambium formation. The expression of HD-ZIP genes is, in turn, activated by auxin, thus completing a positive feedback cycle. ● The phloem-expressed miRNAs further define HD-ZIP gene expression domains by limiting HD-ZIP transcript stability in the phloem-forming regions of the procambium/cambium. The expression domains of miRNAs 165 and 166 overlap considerably with those of KAN genes in Arabidopsis phloem tissues and abaxial leaf domains, and these miRNAs can directly regulate HD-ZIP function. Thus, overexpression of miRNA 165 or 166 leads to enhanced degradation of HD-ZIP transcripts, thereby phenocopying HD-ZIP loss-of-function mutants.
  • 15. The WOX/PXY/CLE41/44 signalling module - ● A diffusion gradient of peptide signaling molecules originating from differentiating phloem cells acts as key regulator of vascular cambium function and patterning. The three cle genes (cle41, 42, and 44) that possess tdif activity (cle/tdif) are expressed and processed into peptide signalling molecules in phloem cells, and the resulting peptides subsequently diffuse into the apoplast to reach neighbouring cells. CLE41, CLE42, and CLE44 are the members of the CLAVATA3/EMBRYO SURROUNDING region-related (CLE) gene family, they encode proteins that are post-translationally processed to form 12-amino acid signalling peptides. These peptides were initially identified as ‘tracheary element differentiation inhibitory factors’ (tdifs). ● Phloem intercalated with xylem/tdif receptor (pxy/tdr), is the product of leucine-rich repeat receptor- like kinase (lrr-rlk) gene, acts as a functional receptor for cle/tdif peptides. The spatial arrangement of CLE/TDIF peptide production in phloem cells, and of PXY/TDR receptor expression in
  • 16. CLE/TDIF peptides (red spheres) originating from phloem cell types diffuse throughout the apoplast and are sequestered by the PXY/ TDR receptor (green rectangles) which is specifically expressed in cambial cells. The polar activation of PXY/TDR signalling leads to cambial cell polarization and results in periclinal division. PXY/TDR signalling also promotes wox4-mediated cambial cell proliferation and promotes stem cell fate by inhibiting xylem differentiation.
  • 17. ● CLE/ TDIF peptide signalling through the PXY/TDR receptor stimulates procambial/cambial cell proliferation and inhibits xylem differentiation. ● The expression of the wox4 (wuschel-related homeobox) transcription factor is up regulated due to pxy/tdr signal transduction. WOX4 is specifically expressed in the procambium/cambium stem cell niche where it functions to stimulate cell proliferation.
  • 18. Differentiation of xylem cell types - The two main steps in the maturation of xylem tracheary elements are secondary cell wall formation and PCD (programmed cell death). A network of transcription factors that regulate the expression of numerous genes are identified that are directly involved in the biosynthesis of secondary cell walls and in PCD. The ‘master regulator’ genes are thought to be positioned near the top of transcriptional cascades that control the xylem differentiation process and direct it to specific end points. ● Initiation of tracheary element differentiation - Vnd7 and vnd6 belong to a seven-member gene family encoding vnd (vascular-related nac domain) transcription factors whose expression led to tracheary element differentiation. Expression of VND7 and VND6 is specifically localized to developing protoxylem and metaxylem respectively. The
  • 19. Programme places these genes at, or near the top of, the transcriptional cascade regulating xylem tracheary element differentiation. Vni2 (vnd-interacting 2) is a transcriptional repressor protein that binds to vnd proteins and inhibit vnd7- mediated gene transcription. The VNI2 protein is targeted for degradation when VND7 expression is required for protoxylem tracheary element differentiation.
  • 20. ● Initiation of fibre differentiation - The expression of nac domain containing transcription factor snd1 is sufficient to differentiate non vascular cell types into fibre like cells. Like VND6 and VND7, SND1 regulates a transcriptional cascade that ultimately activates the specific genes necessary for secondary cell wall biosynthesis. The ectopic overexpression of snd1 results in uniform deposition of secondary cell walls in contrast to the helical or pitted secondary cell walls observed in protoxylem and metaxylem tracheary elements. SND1 functions redundantly with two other NAC transcription factors, NST1 and NST2, to control secondary cell wall formation of all fibre types in Arabidopsis. Single loss-of-function mutants of snd1 or nst1 have no observable phenotype, but developing fibres in the snd1nst1 double mutant retain the general fibre cell shape but have no secondary cell walls. Vnd6, vnd7, and snd1 share significant functional overlap in their ability to activate the downstream transcriptional network and the general metabolic machinery required to form secondary cell walls.
  • 21. The secondary cell wall transcription network converges on MYB46 and MYB83 - ● the secondary cell wall NAC domain transcription factors (VND6,VND7, SND1, NST1 and NST2) binds to SNBE (secondary wall NAC binding element) regulatory regions in the promoter of target genes and activates transcriptional network for secondary cell wall formation. ● The promoters of myb46 and myb83 contain several snbe promoter elements and direct targets of secondary cell wall genes. Double myb46 myb83 knockout mutants are defective in secondary cell wall formation. In ‘seedling lethal’ phenotype of myb46 myb83 plants, vascular tissue formation is completely abolished or the integrity of secondary cell walls is severely compromised. ● The master switch, snd1, activates the expression of myb46 and myb83, along with other genes, including snd3, myb103, and knat7 (which do not appear to make as prominent a contribution to the extension of the network).
  • 22. ● Dominant negative repression of each of these downstream genes resulted in reduced secondary cell wall thickening of both interfascicular fibres and xylary fibres, but not in tracheary elements. ● Snd2, snd3, and myb103 constructs were able to activate the promoters for genes involved in cellulose biosynthesis. ● Myb52 and myb54 constructs activated promoters for genes involved in cellulose, xylan, and lignin biosynthesis, (indicative of a more general role for these two mybs in regulation of cell wall biosynthetic enzymes). ● Myb46 and/or myb83 influence the expression of four transcription factors (knat7, myb4, myb7, and myb32) that function as transcriptional repressors. They repress the expression of master switches such as SND1 and also directly or indirectly repress the expression of genes involved in secondary cell wall biosynthesis. ● Knat7 works as both a positive and negative regulator of different genes involved in secondary cell wall biosynthesis.
  • 23. ● In the absence of KNAT7 function, the expression of two secondary cell wall cellulose synthase genes, a number of hemicellulose biosynthesis genes and the majority of lignin biosynthesis genes is increased. In arabidopsis, the overexpression of KNAT7 led to thinner secondary cell wall phenotypes which shows that it acts as a negative regulator of secondary cell wall deposition. ● Myb46 activates the expression of the myb4, myb7, and myb32 genes. These function as potent transcriptional repressors. MYB4 and MYB32 also function to repress lignin biosynthesis, with MYB32 negatively regulating general phenylpropanoid biosynthesis genes and MYB4 specifically suppressing the expression of the C4H gene, which encodes the first committed step in the phenylpropanoid pathway.
  • 24. Cellulosic secondary cell wall - The secondary cell walls of flowering plants is predominantly composed of cellulose accompanied by lesser amounts of hemicellulose and lignin. Most of the genes involved in the biosynthesis of each of the three main components have been identified. The lignification of the secondary cell wall generally occur after the initial deposition of the cellulosic components that is initiated in a spatially distinct manner. There lies significant parallels between primary and secondary cell wall cellulose synthesis. In both cases, cellulose synthesis complexes (cscs) composed of 36 cesa (cellulose synthesis A) isoform subunits catalyse the linear polymerization of glucose molecules. Distinct subgroups of cesa genes appear to be involved in cellulose biosynthesis in primary or in secondary cell walls. In arabidopsis, the products of the cesa4, cesa7, and cesa8 genes
  • 25. The length of individual cellulose chains ranges from 500 to 2000 glucose molecules in primary cell walls, but can extend to >10 000 glucose molecules in secondary cell walls. A high density of cscs have been localized to specific plasma membrane domains immediately below that developing secondary walls. In Arabidopsis root protoxylem, microtubule bundles oriented along the borders of the developing secondary cell wall thickening helped to organize functional cscs at particular regions of the plasma membrane. Hemicellulose are branched cell wall matrix polysaccharides composed of glucose mannose or xylose. They are synthesized in the Golgi and the hemicellulose containing vesicles are trafficked to specific plasma membrane domains during secondary cell wall formation. Glucuronoxylan is the most abundant hemicellulose found in the secondary cell walls of dicotyledonous plants and is thought to function as the major cellulose crosslinking component in secondary cell walls.
  • 26. Lignification and programmed cell death - The cellulosic secondary cell wall undergoes lignification in tracheary elements and fibers. Lignin imparts both increased structural stability and water impermeability to the cell wall. The failure of lignin biosynthesis leads to irregular xylem (IRX) phenotypes. The process of lignification is tightly controlled both temporally and spatially. In protoxylem, the lignin polymerization is restricted to narrow helical or annular zones of secondary cell wall deposition and in metaxylem it occurs in reticulate pattern.
  • 27. The lignin biosynthesis pathway can be divided into two parts. The first is the general phenylpropanoid pathway, a multistep reaction sequence that generates precursors not only for synthesis of lignin monomers (monolignol alcohols), but also for the synthesis of other phenylpropanoid compounds such as flavonoids, tannins, phenolic esters, and acids. The second pathway is more specific monolignol biosynthetic pathway that provides substrates for the enzymes encoded by members of the ccr, comt, f5h, and cad gene families. The metabolic reactions required for monolignol biosynthesis are believed to operate in the cytosol, or perhaps in the region of the cytosol directly associated with the endoplasmic reticulum. In order for monolignols to participate in polymerization to form the final lignin structure, they must move from their site of synthesis, across the plasma membrane to the cell wall. They potentially exit the cell by passive diffusion. In arabidopsis, several abc transporters facilitate the export of a wide range of low molecular weight, hydrophobic substrates, including auxin, it is possible
  • 28. A set of candidate ABC transporters for monolignol export was previously identified based on their co-expression with phenylpropanoid biosynthesis genes in developing arabidopsis inflorescence stems. Lignin polymerization - The oxidation of the monolignol molecule is catalysed by one or more peroxidases and/or laccases, and the resulting radical is then coupled with a phenoxy radical on the growing lignin chain, through a process referred to as endwise polymerization. The laccases LAC4 and LAC17 are necessary for normal lignification of Arabidopsis fiber cell walls and, to some extent, of tracheary elements. Expression of the LAC4 gene was also found to be up- regulated in response to overexpression of the MYB58 transcription factor. Lignin is synthesized by dehydrogenative polymerization of phenyl propanoid units, namely, coniferyl alcohol, sinapyl alcohol and coumaryl alcohol, which corresponds to guaiacyl (G), syringyl (S) and p-hydroxyphenyl (H) structures of lignin, respectively.
  • 29. In Arabidopsis, tracheary elements have secondary cell walls composed primarily of g-lignin while the walls of the interfascicular fibers are s- lignin rich. In Arabidopsis, tracheary elements have secondary cell walls composed primarily of g-lignin while the walls of the interfascicular fibers are s- lignin rich. The first stage of lignification during xylem development involves the incorporation of a mixture of h-lignin (dominated by 4-hydroxy ring structures) and g-lignin in the middle lamella and cell corners. In the next phase of wall lignification, the primary cell wall and outer layers of the secondary cell wall are lignified primarily with g-lignin. The last stage of lignin deposition is directed to the innermost layer of the secondary cell wall, and in fibers it is largely s-lignin that is formed at this stage.
  • 30. Programmed cell death - During fibre development, the thick secondary cell wall is formed over an extended period, whereas tracheary element differentiation progresses quickly from secondary cell wall deposition to pcd. The expression of several genes functionally associated with PCD is correlated with xylem development. Some genes [e.G. XYLEM CYSTEINE PROTEASE1 and 2 (XCP1 and XCP2); BIFUNCTIONAL NUCLEASE1 (BFN1)] have also been shown to be directly activated by both the VND7 and VND6 transcription factors. Cysteine protease plays a role in executing pcd. In gene transcript profiling in the zinnia tracheary element differentiation cell culture system, the large central vacuole of the nascent tracheary element cell plays a critical role in pcd. Modifications or disruptions of the tonoplast (vacuolar membrane), and accompanying changes in the vacuolar contents, define the initial stage of PCD.
  • 31. The subsequent rupture of the vacuole and release of digestive enzymes such as nucleases and proteases results in digestion of all the cell contents, leaving only the cell wall intact. A study in Poplar has confirmed that tracheary elements undergo PCD and associated vacuolar collapse much earlier than do fibres. In tracheary elements, vacuolar collapse marks the PCD, while PCD in fibres starts with DNA degradation and cellular dismantling. Tracheary element PCD occurs rapidly, with the vacuolar implosion requiring only a few minutes, and the clearance of the remainder of the cell contents is completed within a few hours whereas fibre PCD takes much longer. The non-cell-autonomous lignification model suggests that non-lignifying cells such as xylary parenchyma cells, positioned adjacent to lignifying cells such as tracheary elements, are capable of synthesizing monolignols and exporting them to the cell wall of the neighbouring lignifying cells. In Zinnia cell cultures, these parenchyma-like cells may act as ‘good neighbours’ for the differentiating tracheary elements and provide them with