Regeneration Around Wounds and the Control of Vascular Differentiation

The question which was the basis of this work was whether (a)vascular regeneration around wounds includes a replacement ofdamaged tissues or (b) only new vascular strands, which arenormally formed from the cambium, are diverted around wounds.It was found that in Coleus and Cucumis no connections are formedto damaged sieve tubes and vessels, so that their continuityaround wounds is not restored. Pisum plants were wounded underconditions in which growth could not be influenced and the areaof the xylem in cross-section was measured 1 month later. Thewounds, which damaged the vascular tissues, significantly increasedvascular differentiation, indicating the replacement of a longnon-functional region of damaged tissues. The results indicatethat in the intact plant vascular differentiation is controllednot only by stimuli from the leaves but also by the capacityof the mature vascular system to transport these stimuli.     

Regeneration of Tissues in Wounded Stems: A Quantitative Study

When a dicotyledonous stem is wounded by longitudinally splittinga young internode into halves, cells near the cut surface proliferateto form a callus within which vascular tissues differentiateand tend to restore a vascular cylinder in each half. Threephases of regeneration after wounding were identified and quantifiedin stems of three Solanaceous species. (1) In an initial ‘lag’phase, lasting about 2 d, neither cell division nor enlargementwere detected, but mitotic figures were observed within about300 µm of the cut surface. (2) Throughout a second, ‘division’phase, from about days 2–10, cell division and enlargementoccurred. Both were initiated mainly in the two cell layersnearest the surface. A mass of callus formed, with new cellwalls mostly parallel to the surface. Cell enlargement laggedbehind cell division for the first few days, so that mean radialcell diameter decreased until day 6, thereafter remaining almostconstant at 30–40 µm. Towards the end of this phase,mitoses ceased within the callus except in the positions ofthe future vascular and cork cambia, where radial cell diameterfell towards a constant 15–20 µm. (3) During a third,‘differentiation’ phase, cell division was restrictedto the cambial zones, and derivatives differentiated into cork,phloem or xylem according to position. The rate of increasein cell number per transect was 1.5–2.0 cells d^–1,of which more than half was xylem. Capsicum annuum L., sweet pepper, Lycopersicon esculentum Mill., tomato, cambium, cell division, differentiation, regeneration, wounding of stems, xylem     

Role of Cytokinin in Vessel Regeneration in Wounded Coleus Internodes

Cytokinin was found to be a controlling or limiting factor invessel regeneration around a wound in internodes of Coleus blumeiBenth. in which the endogenous cytokinin level was minimized.The cytokinin was applied in aqueous solution to the base ofexcised, mature internodes that had an active vascular cambium.Each internode also received IAA in lanolin at its apical end.Under low (0.1 %, w/w) or high (10%, w/w) auxin concentrations,the control internodes (without exogenous cytokinin) exhibitedsmall amounts of vessel regeneration. At appropriate concentrationszeatin, kinetin and 6-benzylamino-purine (BAP) induced a significantincrease in vessel regeneration around the wound. The threecytokinins also induced novel patterns of supplementary regenerationfurther from the wound surface. Kinetin and BAP showed the strongestpromoting effect at 5 and 10 µg ml^–1, while zeatinwas most effective at 20 µg ml^–1. At a low (0.1%) auxin level zeatin was the most effective cytokinin, whereaskinetin was the most effective one at high (1 %) auxin. An inhibitoryeffect on vessel regeneration was observed at the highest kinetinconcentration tested (50 µg ml^–1). The regenerationof vessels induced by cytokinin was very polar. Many more regeneratedvessel members differentiated below the wound than above it,and the regeneration process proceeded acropetally from thebase of the internode to its upper parts. Our results implya basipetal polar increase in cambium responsiveness along thestem axis from internode 5 to 7. The possible significance ofsuch a basipetal increase in cambium sensitivity in wood formationin trees is discussed. Auxin, Coleus blumei, cytokinin, vascular differentiation, vessel regeneration, wound xylem     

Regeneration of Soft Tissues Is Promoted by MMP1 Treatment after Digit Amputation in Mice

The ratio of matrix metalloproteinases (MMPs) to the tissue inhibitors of metalloproteinases (TIMPs) in wounded tissues strictly control the protease activity of MMPs, and therefore regulate the progress of wound closure, tissue regeneration and scar formation. Some amphibians (i.e. axolotl/newt) demonstrate complete regeneration of missing or wounded digits and even limbs; MMPs play a critical role during amphibian regeneration. Conversely, mammalian wound healing re-establishes tissue integrity, but at the expense of scar tissue formation. The differences between amphibian regeneration and mammalian wound healing can be attributed to the greater ratio of MMPs to TIMPs in amphibian tissue. Previous studies have demonstrated the ability of MMP1 to effectively promote skeletal muscle regeneration by favoring extracellular matrix (ECM) remodeling to enhance cell proliferation and migration. In this study, MMP1 was administered to the digits amputated at the mid-second phalanx of adult mice to observe its effect on digit regeneration. Results indicated that the regeneration of soft tissue and the rate of wound closure were significantly improved by MMP1 administration, but the elongation of the skeletal tissue was insignificantly affected. During digit regeneration, more mutipotent progenitor cells, capillary vasculature and neuromuscular-related tissues were observed in MMP1 treated tissues; moreover, there was less fibrotic tissue formed in treated digits. In summary, MMP1 was found to be effective in promoting wound healing in amputated digits of adult mice.     

STUDIES ON SARGASSUM. I. A LIGHT MICROSCOPIC EXAMINATION OF THE WOUND REGENERATION PROCESS IN MATURE STIPES OF S. FILIPENDULA

Regrowth from wounded stipe explants of Sargassum can be divided into four stages based on cytological changes. The first stage involves changes associated with the wound reactions and the formation of a wound epidermis. The second stage includes the formation of a well defined medullary pit with meristematically active cells around its periphery. Several “bud primordia” are also formed which begin to grow by cell division towards the wound surface. The third stage involves a period of internal tissue differentiation in the “bud primordia” such that mitotic activity is localized in the bud tip and the basal cells grow by cell elongation. The fourth stage marks a major change in the morphology of the regeneration branch from a tubular structure to that of a flattened blade. This change in morphology is preceded by the formation of an apical pit around which the flattened growth appears to be organized.     

Naturally Occurring Regenerative Differentiation of Xylem Around Adventitious Roots in Luffa cylindrica Seedlings

Regeneration of xylem induced by adventitious root formationin the hypocotyl of Luffa cylindrica Roem. seedlings is described.This naturally occurring form of xylem regeneration involvesthe formation of a bypass of regenerated tracheary elementsaround a root without external severance of the vascular strands.The regeneration of xylem around an adventitious root is polarand is very similar in its developmental pattern to the well-knownxylem regeneration induced by wounding vascular strands. Adventitious root formation, Luffa cylindrica Roem, regenerated tracheary elements, vascular differentiation, xylem regeneration     

Naturally Occurring Regenerative Differentiation of Xylem Around Adventitious Roots in Luffa cylindrica Seedlings

Regeneration of xylem induced by adventitious root formationin the hypocotyl of Luff a cylindrica Roem. seedlings is described.This naturally occurring form of xylem regeneration involvesthe formation of a bypass of regenerated tracheary elementsaround a root without external severance of the vascular strands.The regeneration of xylem around an adventitious root is polarand is very similar in its developmental pattern to the well-knownxylem regeneration induced by wounding vascular strands. Adventitious root formation, Luffa cylindrica Roem, regenerated tracheary elements, vascular differentiation, xylem regeneration.     

Prevention of auxin-induced vascular differentiation in wound callus by surface-to-surface adhesion between calluses of stock and scion in cactus grafts

The relationship between formation of CVB, which connects vascularcut ends of stock and scion, and the condition of tissue whereCVB is expected to be induced was studied using a cactus graftcombination of Notocactus submammulosus var. pampeanus youngseedlings on Hylocereus trigonus plants. When a scion with its basal part removed by a transverse cutwas put onto a transverse cut surface of a stock with a distanceof 1 mm between the vascular cut ends of both graft components,CVB was formed in only 13% of the grafts in the callus massmade by adhesion between calluses of stock and scion. The percentagearose to ca. 100% when 100 ppm NAA was applied to the scionapices. This promotive effect of NAA decreased with increasingtime from grafting to NAA application. When wound calluses of stock and scion were prevented from contactonly at the portion between the vascular cut ends of stock andscion by introducing a piece of aluminium foil into the graftunion, CVB was formed in 80% of the grafts in the callus ofthe stock without NAA application. In the case where the scionwas grafted at right angle onto an additional longitudinal cutsurface made 1 mm from the vascular bundle of the stock withremaining intact parenchyma between this cut surface and thevascular bundle of the stock, CVB was not formed even when NAAwas applied. These results suggested that wound response wasa prerequisite for CVB differentiation and that surface-to-surfaceadhesion of calluses inhibited CVB formation by making calluscells differentiate into quiescent parenchyma cells rapidly.The mechanism of this phenomenon is discussed. (Received September 29, 1977; )     

Wound healing in the trematode Schistosoma

The ability of adult Schistosoma mansoni to effect wound healing over an exposed surface has been demonstrated. In transected worm segments a new external plasma membrane formed over the exposed tegumental cytoplasm. An elevated leading edge of tegument developed around the margin of the wound; the surface of this region was highly convoluted and there was a proliferation of membranous bodies within its cytoplasm. Inward migration of the leading edge over the exposed internal tissues took place. The resulting new tegument lacked spines and sensory endings. There was no regeneration of basal lamina or tegumentary cytons. In vitro maintenance of worm segments for 3 weeks did not give rise to any major ultrastructural changes in the tissues away from the wound.     

The role of cytokinin in sieve tube regeneration and callose production in wounded coleus internodes

Cytokinin proved to be a controlling factor in sieve tube regeneration around wounded collateral bundles in an in vivo system in which the endogenous cytokinin level had been minimized. Both kinetin and zeatin were applied in aqueous solution to the bases of excised, mature internodes of Coleus blumei Benth. that had an active vascular cambium. Each internode also received indoleacetic acid (IAA) in lanolin at its apical end. Under either low (0.1% w/w) or high (1.0% w/w) auxin concentrations, the control internodes (without exogenous cytokinin) exhibited small amounts of sieve tube regeneration. At appropriate concentrations, both kinetin and zeatin induced a significant increase in sieve tube regeneration around the wound. However, the highest concentration of kinetin tested (50 μg/mL) completely inhibited this process. Kinetin was the most effective with high auxin (1.0% IAA), while zeatin was the most effective with low auxin level (0.1% IAA). Kinetin and zeatin showed the strongest promotive effect at 10 μg/mL and 20 μg/mL, respectively. Both cytokinins also induced supplementary phloem regeneration further from the wound surface. In addition to their effects on vascular tissue regeneration, both cytokinins promoted callose production. This was most evident on the sieve plates of the regenerated sieve tube members and on the walls of the parenchyma cells around the wound. The largest deposits of callose were found in both regenerated sieve tube members and parenchyma cells at the highest cytokinin concentration tested (50 μg/mL). The possible role of cytokinin in controlling callose accumulation in the sieve tubes during autumn is discussed.     

Mechanisms of arm-tip regeneration in the sea star,Leptasterias hexactis

Summary Wound healing and regeneration following amputation of arm-tips of the sea star, Leptasterias hexactis, are described using light microscopy, SEM, TEM, and [³H] thymidine autoradiography. The process can be divided into a number of stages. Initially, the wound is closed by contractions of the stump-tip. Re-epithelialization then occurs through migration of epidermal cells from adjacent areas over the wound to form a thin wound epidermis. This is converted into a thicker, permanent covering in concurrence with the onset of cell cycle activity in the wound epidermis and adjacent epidermal regions. Histolysis and phagocytosis of damaged tissues occur beneath the new epidermis and a small connective tissue scar develops at the wound site within which muscle differentiates. At this time, elevated levels of [³H]thymidine incorporation are initiated in the sub-epidermal tissues of the arm-tip. A variety of differentiated cell types enter the cell cycle including cells of the parietal peritoneum, lining of the radial water canal, and the dermis. Cell division is accompanied by the development of a small new arm-tip complete with terminal ossicle, terminal tentacle, and optic cushion. The radial water canal, radial nerve, and perivisceral coelom extend by outgrowth into this newly developing tip. Accelerated growth of the regenerate then occurs in a zone just proximal to the new tip. There is no evidence of a blastema-like mass of rapidly dividing undifferentiated cells at the tip of regenerating arms. Arm-tip regeneration in this sea star may therefore be best described as a morphallactic-like process in which a true blastema is not formed, but in which scattered cell proliferation plays an essential role.     

Notch与相关调控信号的相互作用在伤口愈合中的调控

皮肤是哺乳动物最重要的组织之一.当皮肤受损时,受损组织通过系列伤口愈合反应的生理和心理作用被修复,实现组织再生.再生反应主要发生在胚胎发育早期,伤口自愈能力随着机体的成熟而减弱;并且哺乳动物的组织重塑过程较为复杂,在不正确的信号引导下,可能引起并发症而导致创面愈合异常.研究表明,伤口微环境的稳态和信号分子的辅助作用是愈...     

Regenerative Xylem in Inflorescence Stems of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

By inserting entomological needles into the lower parts of young inflorescence stems of three-month-old Arabidopsis thaliana (L.) Heynh var. Colombia plants, we studied the process of regenerative xylem production. Regenerative xylem was formed only in one- to two-day-old inflorescence stems but not in older ones. The regenerative vessels originated from re-differentiation of cortical parenchyma. To characterize the process of regenerative xylem formation, we conducted a histological study from the time of wounding to day 30 after wounding. In the first day after wounding the tissues showed no structural responses except for the wounding itself. After six days, regenerative vessel members were already differentiating in a basipetal pattern, forming a vascular bypass around the wound. Regenerative vessel member formation reached a maximal level on the twelfth day after wounding. Sixteen days after wounding the pith parenchyma started to become loose as if indicating tissue senescence. Altogether, vascular regeneration following wounding in inflorescence stems of Arabidopsis thaliana is similar to that in other dicotyledon plants. These findings provide the basis for the use of Arabidopsis thaliana as a model system to study the genetics, physiology and cell biology of wound healing and regenerative vascular tissue formation.     

Phloem transdifferentiation from immature xylem cells during bark regeneration after girdling in Eucommia ulmoides Oliv

Eucommia ulmoides Oliv. (Eucommiaceae), a traditional Chinesemedicinal plant, was used to study phloem cell differentiationduring bark regeneration after girdling on a large scale. Hereit is shown that new sieve elements (SEs) appeared in the regeneratedtissues before the formation of wound cambium during bark regenerationafter girdling, and they could originate from the transdifferentiationof immature/differentiating axial xylem cells left on the trunk.Assays of water-cultured twigs revealed that girdling blockedsucrose transport until the formation of new SEs, and the regenerationof the functional SEs was not dependent on the substance providedby the axis system outside the girdled areas, while exogenousindole acetic acid (IAA) applied on the wound surface acceleratedSE differentiation. The experiments suggest that the immaturexylem cells can transdifferentiate into phloem cells under certainconditions, which means xylem and phloem cells might share someidentical features at the beginning of their differentiationpathway. This study also showed that the bark regeneration systemcould provide a novel method for studying xylem and phloem celldifferentiation. Key words: Bark regeneration, Eucommia ulmoides Oliv., immature xylem cells, sieve elements, transdifferentiation Received 19 November 2007; Revised 23 January 2008 Accepted 24 January 2008     

Anatomical Changes Which Occur in Cuttings of Agathis australis (D. Don) Lindl 2. The Initiation of Root Primordia and Early Root Development

Cuttings of Agathis australis undergo complex anatomical changesin the sub-base and base. These changes include wound responsesin addition to the processes leading to adventitious root production.Although the root pnmordia form in the mid cortex the firstevents are associated with divisions in the interfasicular regiona few millimetres above the base of the Cutting. This is followedby differentiation into tracheids and phloem which then areoutwards and downwards into the mid cortex. When the inducedvascular strand is only a few cells wide, conditions at theadvancing front are most favourable for primordium formation.If sheets of vascular tissue occur, there is neither the spacenor the focal point for primordia to initiate. In cuttings fromolder material there are abundant resin canals, sclerenchymaand branch traces. These may reduce the amount of parenchymatissue to such a low level that potential primordial sites areno longer present and root formation is prevented. Organization is not observed until over 1500 cells are presentand at about this stage the beginning of organized cell arrangementcan be seen at the site of the apex of the primordium. Untilthis time the progress towards a primordium could not be saidto be ‘determined’. Although the lag phase before any morphological or anatomicalchanges are observed is variable in duration, the time takenfor the period of tracheid development and then for primordiumorganization and outgrowth is fairly constant, taking about2 weeks for each of the two phases. Evidence suggests that thevariation between species is probably in the duration of thelag phase and in the precise site of origin and pattern of theearly events. Once the primordium has formed the events leadingto root formation are probably similar for most species bothfor adventitious and lateral roots. Agathis australis (D. Don) Lindl, kauri, cuttings, wound responses, vascular connections, root primordia, root anatomy     

Calcium Oxalate Crystals in Developing Seeds of Soybean

Young developing soybean seeds contain relatively large amountsof calcium oxalate (CaOx) monohydrate crystals. A test for Caand CaOx indicated that Ca deposits and crystals initially occurredin the funiculus, where a single vascular bundle enters theseed. Crystals formed in the integuments until the embryo enlargedenough to crush the inner portion of the inner integument. Crystalsthen appeared in the developing cotyledon tissues and embryoaxis. All crystals formed in cell vacuoles. Dense bodies andmembrane complexes were evident in the funiculus. In the innerintegument, cell vacuoles assumed the shape of the future crystals.This presumed predetermined crystal mould is reported here forthe first time for soybean seeds. As crystals in each tissuenear maturity, a wall forms around each crystal. This intracellularcrystal wall becomes contiguous with the cell wall. Integumentcrystals remain visible until the enlarging embryo crushes theinteguments; the crystals then disappear. A related study revealedthat the highest percent of oxalate by dry mass was reachedin the developing +16 d (post-fertilization) seeds, and thendecreased during late seed maturation. At +60 d, CaOx formationand disappearance are an integral part of developing soybeanseeds. Our results suggest that Ca deposits and crystals functionallyserve as Ca storage for the rapidly enlarging embryos. The oxalate,derived from one or more possible metabolic pathways, couldbe involved in seed storage protein synthesis. Copyright 2001Annals of Botany Company Calcium, crystals, development, Glycine max, ovule, oxalate, seed, soybean     

Investigating the developmental onset of regenerative potential in the annelid Capitella teleta

An animal's ability to regrow lost tissues or structures can vary greatly during its life cycle. The annelid Capitella teleta exhibits posterior, but not anterior, regeneration as juveniles and adults. In contrast, embryos display only limited replacement of specific tissues. To investigate when during development individuals of C. teleta become capable of regeneration, we assessed the extent to which larvae can regenerate. We hypothesized that larvae exhibit intermediate regeneration potential and demonstrate some features of juvenile regeneration, but do not successfully replace all lost structures. Both anterior and posterior regeneration potential of larvae were evaluated following amputation. We used several methods to analyze wound sites: EdU incorporation to assess cell proliferation; in situ hybridization to assess stem cell and differentiation marker expression; immunohistochemistry and phalloidin staining to determine presence of neurites and muscle fibers, respectively; and observation to assess re-epithelialization and determine regrowth of structures. Wound healing occurred within 6 h of amputation for both anterior and posterior amputations. Cell proliferation at both wound sites was observed for up to 7 days following amputation. In addition, the stem cell marker vasa was expressed at anterior and posterior wound sites. However, growth of new tissue was observed only in posterior amputations. Neurites from the ventral nerve cord were also observed at posterior wound sites. De novo ash expression in the ectoderm of anterior wound sites indicated neuronal cell specification, although the absence of elav expression indicated an inability to progress to neuronal differentiation. In rare instances, cilia and eyes re-formed. Both amputations induced expanded expression of the myogenesis gene MyoD in preexisting tissues. Our results indicate that amputated larvae complete early, but not late, stages of regeneration, which indicates a gradual acquisition of regenerative ability in C. teleta. Furthermore, amputated larvae can metamorphose into burrowing juveniles, including those missing brain and anterior sensory structures. To our knowledge, this is the first study to assess regenerative potential of annelid larvae.     

The Effect of a Grafted Bud on Vascularization of the Petiole in Phaseolus, Datura and Lycopersicon

The radially-organized petiole of Phaseolus and the dorsiventralpetioles of Datura and Lycopersicon were used as stocks in budgrafting. Petiolar structure was examined after some weeks'growth of the scion, during which the grafted petiole came tofunction as a stem in supporting normal, vigorous shoot growthand was not abscised even at the end of the growing season.Below the graft union, reactivated petiolar cambium producedmassive amounts of secondary tissue with greatly enlarged vessels.Cambial activity was confined to the existing vascular bundlesexcept for the development of a little inter-fascicular cambiumin young, grafted Phaseolus petioles. Datura petioles woundedbelow the graft union, by a cut into the petiolar are from eitherthe abaxial or the adaxial surface and removal of a 1 cm lengthof tissue, responded by restoring the vascular are (abaxialwounds) or almost completing a vascular ring (adaxial wounds).In grafted, wounded Lycopersicon petioles the presence of deadxylem caused the separation of cambium regenerated from thecut vascular are and that arising in relation to the centralwound surface. A similar response, in which stimulated internalphloem plays an important part, occurred in certain woundedLycopersicon stems. The results are discussed in terms of thegradient induction hypothesis. graft, petiole, wound, cambium, xylem, phloem, Phaseolus multiflorus, Datura stramonium, Lycopersicon esculentum, bean, thornapple, tomato