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Development of gelatinous (reaction) fibers in stems of Gnetum gnemon (Gnetales)¹

²Harvard Forest, Harvard University, Petersham, Massachusetts 01366 USA; and National Tropical Botanical Garden, 3530 Papalina Road, Kalaheo, Hawaii 96741 USA

Received for publication November 5, 2002. Accepted for publication February 21, 2003.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
In extraxylary tissues of the stem Gnetum gnemon produces gelatinous fibers that can also function as reaction or tension fibers. These gelatinous fibers occur in all axes in the outer cortex and in displaced axes progressively in the middle and inner cortex and finally in the secondary phloem. Early cell differentiation in the cortex produces initials of laticifers that are unique in gymnosperms. Subsequently narrow fibers differentiate from cells that undergo both extensive passive elongation, as a result of internodal elongation, together with their active apical intrusive growth. Outer fibers always complete secondary wall development and become an important mechanical component of stems. Differentiation of fiber initials continues in the middle and inner cortex, but secondary wall formation can only be determined by a gravimorphic stimulus that produces eccentric development of fibers. Further eccentric development of fibers then continues in the outer secondary phloem from dedifferentiated phloem parenchyma cells that initially undergo extensive intrusive growth. All such cells have characteristic features of tension fibers of angiosperms. They exhibit a pronounced purely cellulosic innermost layer of the secondary wall (Sg layer). In addition, fiber initials are coenocytic, including up to eight nuclei that become distributed uniformly throughout the length of the cell. Mature macerated fibers are markedly brittle, making accurate length measurements difficult. Although cytologically uniform, these fibers thus originate from two kinds of initial (primary and secondary). They also differ in their response to a gravimorphic stimulus determined by their times of inception and their eccentric location. These cells show a suite of positional and gravimorphic responses that illustrate the complexity of plant cell differentiation.

Key Words: fiber development • gelatinous fiber • Gnetales • Gnetum gnemon • reaction fiber • stem anatomy

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Gelatinous fibers, which appear to function as reaction (i.e., tension) fibers, occur in an extraxylary position in both orthotropic and plagiotropic axes of Gnetum gnemon, a tree species in a genus largely characterized by its woody viny habit. Experimental manipulation has shown that the fibers may function mechanically by inducing tensions that can either maintain the horizontal position of plagiotropic axes or re-erect orthotropic axes that have been displaced from the vertical (Tomlinson, 2001 ). This paper shows how these stem fibers are of three different kinds in terms of their development and have different diameters yet are all alike in having the cell wall features familiar in the tension wood fibers of dicotyledons. Apart from their extraxylary position and unique occurrence in a gymnosperm, the tension fibers of Gnetum are coenocytic, a condition that seems not to have been reported previously for tension wood fibers. Tension fibers also occur in leaves of Gnetum, but are not reported on in detail here.

Earlier observations and experiments have shown that reaction fibers occur in three positions in stems of Gnetum gnemon (Tomlinson, 2001 ) and produce striking asymmetry in extraxylary tissues (Figs. 3–5). In both orthotropic and plagiotropic axes, narrow fibers are produced concentrically in the outer cortex of stems without regard to their orientation (i.e., they are obligate in their origin). Subsequently wider fibers can be developed eccentrically in the middle and inner cortex in an opportunistic manner as a gravimorphic response. This characteristically occurs on the upper side of leaning orthotropic axes or in plagiotropic axes also on the upper side either with increasing age or with displacement. In yet older axes, further narrow reaction fibers occur eccentrically in the outer secondary phloem to such an extent that they may virtually replace all phloem tissue. This results in three extraxylary regions with fibers on the upper side (Fig. 4, Co 1, Co 2, Phf), but only Co 1 fibers on the opposite side (Fig. 5, Co 1) at the same level. Clearly the sequence of developmental events is complex and requires detailed investigation.

View larger version (166K): [in this window] [in a new window]   Fig. 1–9. Gnetum gnemon. 1. Thick median section of apex of shoot with enclosed new apical bud (Ab). Scale = 3 mm. pet = base of petiole; co = cortex; m = medulla; scl = sclereids. 2. Transverse section (T.S.) of youngest extended internode with primary vascular bundles (pvb); cortex (co) appears undifferentiated. Scale = 1 mm. m = wide medulla. 3. T.S. of older orthotropic axis bent from the vertical, photographed with part polarized light. Notch (n) indicates orginal upper side; all extraxylary gelatinous fibers on upper side appear brightly birefringent. Scale = 5 mm. 4. Detail of outer region of upper (notched) side of Fig. 3, photographed with part polarized light; gelatinous fibers birefringent. Prominent are fibers of middle and inner cortex (Co 2); less prominent are the narrow fibers of the secondary phloem (Phf). Narrow fibers of outer cortex (Co 1) are not prominent, but cf. Fig. 7. Scale = 500 µm. sec xy = secondary xylem. 5. T.S. of sector from lower side of Fig. 3 photographed with part polarized light; cortical cells appear largely empty and without thick walls. Scale = 500 µm. Co 1 = narrow fibers of outer cortex (cf. Fig. 7), mc = middle cortex without mature fibers, sec xy = secondary xylem. 6. T.S. of outer cortex of extending internode from freehand section stained in Sudan IV. Cortex (co) appears undifferentiated (cf. Fig. 8) except for conspicuously stained initials of laticifers (lc); cf. Fig. 11 . Scale = 50 µm. 7. Outer cortex of youngest extended internode photographed with part polarized light. Narrow outer gelatinous fibers (Co 1) appear conspicuously birefringent. Scale = 50 µm. 8. T.S. of middle cortex of extending internode from paraffin section of partly cleared material; inner cortex with developing sclereids (scl) is to the right. Cell diameter is highly variable and includes narrow intrusive tips of many fiber initials. Scale = 50 µm. 9. Longitudinal section (L.S.) of middle cortex of extending internode with numerous fiber initials (fi) showing intrusive apical growth (cf. Fig. 15 ). Scale = 300 µm; lc = part of laticifer initial

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Stem material at different developmental stages was collected mainly from a mixed population of several trees cultivated at "The Kampong," Miami, Florida, USA. These specimens were abundantly reiterated, and so provided numerous orthotropic stems. Additional material came from a single male specimen at the McBryde Garden of the National Tropical Botanical Garden, Kalaheo, Kauai, Hawaii. Shoots with developing and mature internodes up to stem diameters of 3 cm were fixed in formalin-acetic alcohol (FAA) and after 48 h transferred to 70% ethyl alcohol for transportation. Dissection of shoot apices was facilitated by staining specimens in 1% acid fuchsin in 95% ethyl alcohol.

For older stems and woody axes, freehand sections were made on a sliding microtome at 30–60 µm. Staining included 0.1% aqueous toluidine blue (general stain), iodine-potassium iodide (for starch), phloroglucinol and concentrated hydrochloric acid (for lignin), saturated alcoholic Sudan IV (for lipids), and 1% alcoholic chlorazol black (for pure cellulose). Maceration of developing internodes was done on small slices of material in concentrated HCl : water (1 : 3) in an oven at 55°C for 2–3 h. Older material was macerated as small slivers boiled for 2–3 min in 10% aqueous potassium hydroxide followed, after repeated washing in water, by 20% chromic acid (chromium trioxide) for 15–30 min. Macerated material was mounted and teased apart in glycerin : water (1 : 1) after repeated washing in water. It was found that careful maceration softened material sufficiently for cell separation while still retaining cell contents (e.g., Figs. 18–19). Nuclei could then be stained either in hot aceto-carmine, or iodine-potassium iodide, or acid fuchsin.

View larger version (135K): [in this window] [in a new window]   Figs. 10–19. Gnetum gnemon. Details of cell differentiation in young cortex. 10. L.S. of outer cortex from paraffin section. Outer gelatinous fiber (Co 1) with thick Sg layer of secondary wall (Sg) apparently detached from thin primary wall. Inner fiber initials (fi) remain incompletely differentiated. Scale = 100 µm. 11. Young laticifer initial (lc) from macerated material with characteristic uniformly granular cytoplasmic contents. Nuclei (n) of undifferentiated parenchyma cells remain conspicuous. Scale = 80 µm. 12. L.S. of middle cortex from extending internode. Laticifer initial (lc) with characteristic papillate extrusions to left; gelatinous fiber initial (fi) to right with nonpapillate walls and highly vacuolated contents. Scale = 100 µm. 13. Fiber initial (fi) in L.S. from middle cortex of extending internode with thin primary wall; thin limiting cytoplasm with two groups of free nuclei (n). Scale = 100 µm. 14. Detail of fiber initial (axial direction is horizontal) with cluster of five free nuclei (n). Scale = 40 µm. 15. Detail of tip of fiber initial (fi) with densely stained apical cytoplasm (cyt) detached from cell wall and becoming vacuolated proximally. Scale = 100 µm. 16. Detail of more proximal portion of fiber initial (fi) in Fig. 15 with thin vacuolated cytoplasm and two free nuclei (n). Scale = 100 µm. 17. Detail of tip of mature fiber initial with thin primary wall (pw) extending beyond the thick Sg layer of the secondary wall. Scale = 40 µm. 18. Part of developing fiber initial (fi) from macerated material. Cytoplasm is collapsed, but a single nucleus (n) is conspicuous. Scale = 40 µm. 19. Part of developing fiber initial (fi) with two free nuclei (n) in an unstained macerated preparation. Scale = 40 µm

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Architecture and articulated growth
Gnetum gnemon provides a clear example of Roux's model in the Hallé-Oldeman system of tree architecture (Hallé et al., 1978 ). Orthotropic shoots produce continuous sylleptic plagiotropic branches from primary buds, the decussate phyllotaxis resulting in four branch orthostichies and radial symmetry of trunk axes. Plagiotropic axes also have decussate phyllotaxis but become dorsiventral by continuous rotation of leaf pairs into the horizontal plane by internodal twisting and petiolar torsion. Higher-order branches are infrequently produced but always in the horizontal plane. Each leaf subtends a primary bud and one to two supernumerary serial buds, with the latter functioning as reserve buds, or in outer shoots as reproductive units. Reiterated axes on vegetative parts come from the reserve buds stimulated, either by damage to or tilting of axes, to develop by prolepsis and repeat the architecture of an orthotropic shoot (i.e., Roux's model).

Growth of all axes is rhythmic but highly articulate because of the fairly constant extension of one internode at a time, with intervening rest or dormancy of the shoot apex. Infrequently, and then most often on orthotropic shoots, two or more internodes may extend without an intervening rest period. This articulated construction is related to bud morphology (Fig. 1). There are no bud scales, but the resting apex is protected by a pair of pouched petiole bases that produce a hemispherical cavity in which younger parts are enclosed. Presumed additional protection is provided by tufts of multicellular uniseriate hairs on the inner margin of the petiolar pouch. Resting buds include only two enclosed leaf pairs. The inner pair is represented only by each shallow leaf buttress, while the older pair is differentiated into distinct blade and petiole (Fig. 1). Extension of this pair proceeds in tandem with the development of a new leaf pair.

Extension of the shoot to produce internodes up to 15 cm long begins by extrusion of the older leaf primordial pair through the mouth of the petiolar pouch, followed by internodal extension and expansion that widens this cavity. On plagiotropic shoots the extending axis is floppy and pendulous but becomes rigid and self-supporting as tissues mature. When extension is complete, the apex again enters into a resting phase surrounded by the two pairs of leaf primordia. How this articulated shoot development produces a continuous vascular system remains unexplored.

Primary stem construction
The stem has a eustelic construction (Fig. 2), with about 45 primary vascular bundles in wider axes. In young axes the cortex is differentiated internally from the vascular cylinder by a conspicuous starch sheath that also includes a discontinuous series of irregularly stellate sclereids. Similar sclereids are isolated in the rest of the cortex and the medulla, with a concentration at the top of the internode immediately below the resting bud (Fig. 1, scl). A fascicular vascular cambium is a feature of each vascular bundle early in development (Figs. 20–21). It becomes a continuous cambial cylinder with the advent of an interfascicular cambium (e.g., Fig. 22). This results in a continuous secondary cylinder of xylem and phloem with very broad primary rays (Figs. 3–5). This paper first considers the maturation of the cortex in which the primary reaction fibers are present and then the outer phloem in which secondary reaction fibers develop.

View larger version (181K): [in this window] [in a new window]   Figs. 20–27. Gnetum gnemon. Development of secondary gelatinous phloem fibers. 20. T.S. of vascular bundle in extending internode with protophloem (pphl) and early protoxylem (pxy). Cortex (co) and medulla (m) undifferentiated. Scale = 100 µm. 21. T.S. of vascular bundle at a later stage with onset of collapse of protophloem (cphl) and maturation of early metaxylem (mxy). Primary phloem (phl) has established radial files of cells. Scale = 100 µm. co = cortex; m ;eq medulla. 22. T.S. of part of mature primary vascular bundle with collapsed protophloem (cphl) and vessels (v) in late metaxylem (mxy). Interfascicular cambium in early differentiation. Scale = 75 µm. 23. Tangential L.S. of primary phloem with alternating parenchyma cells (par) and sieve cells (sc), the former with transverse, the latter with oblique end walls. Scale = 75 µm. 24. T.S. of phloem of vascular bundle in secondary stage of development, with intrusive fiber initials (fi) in outermost layers. Scale = 40 µm. 25. Transverse view of cambial region and inner cortex; phloem fiber initials (fi) becoming pronounced in place of former collapsed protophloem. Innermost cortical fibers (Co 2) well developed. Scale = 150 µm. 26. Late stage of development of phloem fibers (Phf), but with some undifferentiated inner cortical fibers (fi) in this sector. Scale = 300 µm. Co 2 = cortical gelatinous fibers; scl = sclereid. 27. Mature stem with innermost gelatinous fibers (Co 2) of cortex all fully differentiated and secondary phloem largely occluded by gelatinous fibers (Phf), cf. Fig. 4 . Scale = 300 µm. scl = sclereids.

Outer cortical fibers differentiate early (Fig. 7, Co 1) as elongated initials with thin primary walls. The subsequent production of a cellulosic secondary wall is artifactually always seen to be detached from the primary wall (Fig. 10). No evidence was found for the dissolution of transverse walls, as with laticifers, in these and other fibers. These outer fibers differentiate sufficiently early that their extension could be passive, i.e., without apical intrusive growth in contrast to later fibers.

In early internodal extension, middle and inner cortical cells appear uniform in transverse section (T.S.) except that outer cells include abundant chloroplasts (Fig. 6). As internodal extension proceeds, fiber initials continue to differentiate in a centripetal direction. Extension is in part passive because growth of fiber initials occurs during internodal elongation but apical intrusive growth also occurs, i.e., active extension. Fiber initials are recognizable in longitudinal section (L.S.) as elongated cells (Fig. 9, fi), which are highly vacuolated and with limited peripheral cytoplasm (Figs. 12–14 and 16). Cell walls remain thin but highly hydrophilic and refractive and stain intensely in safranin/alcian green preparations. As fiber differentiation proceeds, the cortex in transverse sections appears as a network of apparently empty cells (the cell contents are lost) among short undifferentiated parenchyma cells with normal cell contents (Fig. 2, co and Fig. 5, mc).

Evidence for apical intrusive growth is demonstrated by the pointed tips, as seen in L.S. (Fig. 15), with the narrow intrusive tips seen as cells of small diameter in T.S., protruding within intercellular spaces (Fig. 8). The cytoplasm in these tips is densely stained with safranin (Fig. 15) but is not granular as in laticifers and with a gradual transition to the thin vacuolated cytoplasm proximally (cf. Figs. 15–16). Some evidence of polarity occurs because the dense tip cytoplasm is usually directed apically within the internode.

Fiber cytology
A conspicuous feature of fiber initials is their multinucleate condition that results from nuclear division without concomitant wall formation (Fig. 13, n). In young initials this is made evident by clusters of from two to six nuclei in each cell (Figs. 14 and 16, n), suggesting a rapid sequence of mitoses. However, division figures have rarely been observed. Fiber initials are therefore not articulated by breakdown of transverse septa, as is reported for laticifers. As fiber elongation proceeds, the nuclei, which are initially spherical (Fig. 18), become elongated within the narrow cell lumen and contrast with the nuclei of ground parenchyma cells. Nuclei also become dispersed throughout the very long fiber initial so that it is difficult to count their number. The maximum number observed was eight. Fiber initials can remain indefinitely in this incompletely differentiated state without developing a secondary wall.

Mature internode
When internodal elongation has ceased, the mature cortex consists of the outer series of fully differentiated narrow fibers interspersed among chlorophyllous ground tissue. Internally, there are idioblastic laticifers and long immature fibers with thin but refractive primary walls and sparse cell contents, the fibers interspersed among short ground parenchyma cells with relatively dense contents. The starch sheath represents the innermost layer of the cortex, together with an irregular series of stellate, often long-armed sclereids. There is a two- to five-celled layer of parenchyma within the sclereid layer and immediately outside the vascular tissue to which the topographic term "pericycle" might usefully be given (e.g., Figs. 25–26). Vascular differentiation is complete in the larger vascular bundles as phloem and xylem separated by the interfascicular cambium (Fig. 22). The developing and primary phloem (Figs. 20, 21), as described by Behnke and Paliwal (1973) and Paliwal and Behnke (1973) , includes alternate files of long sieve cells (range about 400–850 µm) and files of shorter phloem parenchyma cells (range about 80–210 µm). The parenchyma cells originate by transverse division within a longer procambial or cambial derivative and retain their nuclei (Fig. 23). Radial seriation of phloem cells begins in the developing vascular bundle as protophloem (pphl) and protoxylem (pxy) appear (Fig. 20). It continues in later stages (Fig. 21) so that the fascicular cambium has a very early origin. The protophloem is eventually represented by its crushed elements as an outer cap to the primary phloem (Fig. 22, cphl). Further changes in the cortex and outer phloem are determined by gravimorphic responses.

Late fiber maturation
Cortex
On the upper side of plagiotropic axes, and on orthotropic axes displaced from the vertical, maturation of fiber initials proceeds entirely as a localized response, with initials on the lower side continuing to remain undifferentiated (cf. Figs. 4 and 5). This eccentricity (Fig. 3) appears to be the source of tensions that maintain the horizontal position of plagiotropic axes and re-erect orthotropic axes. The response is therefore the major stimulus for final maturation of gelatinous or reaction fibers. Secondary wall development is completed as in the already mature outer fibers but with much larger resulting cell diameters. In transverse sections the Sg layer of the secondary wall is at first typically collapsed and withdrawn from the primary wall, but at maturity the layer is concentric and clearly multilamellate. The separation of secondary from primary wall is evident even as fibers mature (Fig. 10) and is striking in macerated fibers (Fig. 17). Maturation of cortical fibers is always centripetal, so that middle level fibers always mature before inner fibers.

Primary and secondary phloem
The centripetal process of fiber differentiation continues in the outer phloem and is initiated by expansion and elongation of cells adjacent to the crushed remains of the early primary phloem (Fig. 24). Such cells are initially short phloem parenchyma cells since these cells, unlike sieve cells, are the only elements capable of dedifferentiation (Fig. 23). Also these phloem fiber initials must extend by intrusive growth, i.e., actively as there is no internodal elongation within secondary tissues. The initials consequently progressively penetrate the remains of the early phloem (Figs. 24–26), which is finally obliterated (Fig. 27), and the mature fibers reach a length probably comparable to that of cortical fibers. Fiber differentiation proceeds as in cortical fibers with the establishment of a thick Sg layer, at first appearing convoluted in T.S. (Fig. 26, Phf), but later becoming rigid. Development of large numbers of fiber initials and their intrusive growth results in complete occlusion of the phloem (Fig. 27). Because of their large numbers, fibers toward the cambium are thus likely to be the products of secondary phloem parenchyma cells that have dedifferentiated. Where the process of fiber stimulation is long active, as in orthotropic axes that have been displaced and tied down, the contrast between upper and lower extraxylary tissues is pronounced (Figs. 3–5).

Fiber dimensions
The three topographic fiber types fall into three discrete diameter categories, with little overlap. Mean value (N = 20) is 21 µm for Co 1 fibers (range 15–20 µm); 51.5 µm for Co 2 fibers (range 42.5–67 µm); and 27 µm for Phf fibers (range 22.5–32.5 µm). In transverse view the range appears to be greater because of the tapering ends of fibers (e.g., Fig. 27, Co 2). As indicated earlier, because macerated fibers are brittle and not easily separated, fiber length is difficult to measure precisely. Representative values for the few complete cells measured (N = 10) give a range of 6.5–14 mm for Co 1 fibers, 4–19 mm for Co 2 fibers, and 4–18 mm for Phf fibers. More precision would be misleading because fiber length is partly determined by internode length, which is variable within an order of magnitude on different parts of the tree. The quoted values are certainly minimal.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
The present article demonstrates the complexity of fiber development in the extraxylary tissues of Gnetum gnemon. Further complexity may reside in gelatinous fibers of the leaf axis not considered here. Gelatinous fibers in the stem are distinctive because they are multinucleate. This is perhaps not surprising because many kinds of normal plant fibers are multinucleate (e.g., Esau, 1938 , 1943 ), but there are no reports of coenocytic stages specifically in tension wood fibers of dicotyledons, despite the large amount of literature on the subject. Emphasis has been directed more toward the nature of the cell wall and its variability (e.g., Prodhan et al., 1995 ). The most striking feature is the distinctive and almost wholly cellulosic G-layer (Sg) of the secondary wall, with its shallow helical microfibrillar organization and weak attachment to the primary and outer secondary wall layer (S₁). These features are found in the gelatinous fibers of Gnetum and are suggestive of cell type homologies between Gnetales and dicotyledons.

However, there are unique features in the way in which gelatinous fibers develop in Gnetum because three cell types can be recognized within the continuum of centripetal fiber differentiation in extraxylary tissues. Their progressive development is charted in Fig. 28, which is complicated by the frequency of alternative pathways. The first category (Fig. 28, Fiber type Co 1) includes outer gelatinous fibers that are initiated in elongating internodes and do not show a gravimorphic response. They complete their maturation to form a concentric layer that is of presumed mechanical importance. Such fibers are therefore obligate in their development. Otherwise stem mechanical tissues consist only of the limited amount of primary xylem and sclereids with an idioblastic distribution. The latter largely form a discontinuous layer immediately outside the stele that is gradually completed by differentiation of cubical sclereids in thicker older stems.

View larger version (36K): [in this window] [in a new window]   Fig. 28. Suggested flow chart for the three topographically independent fiber types (Co 1, Co 2, and Phf) in stems of Gnetum gnemon (see Discussion)

These developmental events continue in Gnetum within primary but largely secondary phloem cells (Fig. 28, Fiber type Phf) that dedifferentiate from existing parenchyma cells into fibers under the same continued gravimorphic stimulus. Fiber determination is again an entirely opportunistic process, differing on upper and lower sides of the same axis. Such gelatinous fibers elongate entirely by intrusive growth. Because the later-formed ones can be derived from cambial initials, i.e., are secondary in origin, they are more directly comparable to tension wood fibers of dicotyledons. The process of secondary fiber development in phloem tissues of Gnetum can be so prolonged that virtually the entire phloem sector becomes converted into gelatinous fibers and presumably loses most of its transport capacity (Fig. 27). Transport then becomes the function of the phloem in the lower stem sector in which there is no transformation, the phloem tissue retaining the characteristic features described by Behnke and Paliwal (1973) and Paliwal and Behnke (1973) . These authors make no indication of the presence of fibers in the phloem of Gnetum, presumably because they studied either younger stems not yet capable of any gravimorphic response or only erect orthotropic shoots.

The function of reaction fibers in Gnetum is still imprecisely understood because only an association between the presence of fibers with an eccentric distribution and a self-erecting response that seems to be dependent on induced tensions is observed. This is a common critique in this aspect of plant anatomy as a reverse explanation might suggest that induced tensions are the cause and not the effect of reaction fibers, as reviewed in Wilson and Archer (1977) . Nevertheless, there is clear evidence that tension wood fibers are contractile agents in the establishment of the initially free-hanging roots of Ficus, as described by Zimmerman et al. (1964) . Here, once a stem-attached aerial root with entirely primary vascular organization is planted in a pot, tension wood fibers are developed in newly formed secondary wood. The pot becomes lifted off the ground, i.e., the tension develops only after tension wood fibers are differentiated. Furthermore, this reaction wood is developed concentrically in the root. Such circumstantial evidence implicates reaction fibers in the development of tension. Therefore, fibers of this type, all with the same characteristic wall ultrastructure, can reasonably be expected to perform similar functions.

The observations on Gnetum demonstrate the complexity of reaction tissue formation in plants. In this genus there are different reaction responses in different parts of the same plant (e.g., the contrast both between orthotropic and plagiotropic axes and upper or lower stem sectors) and different responses to the same stimulus in different tissue regions (fibers differentiated under three contrasted developmental regimes). Gnetum may provide a suitable experimental object for elucidating the mechanisms that control cell differentiation and cell wall formation in plants.

There is also now evidence of a cell type in a gymnosperm whose apparent homologue was previously thought to be unique to angiosperms. This raises the evolutionary question whether the similarity is the result of shared ancestry or remarkable convergence.

	FOOTNOTES

 
¹ This research was supported by the Eleanor Crum Professorship of Tropical Botany of the National Tropical Botanical Garden. Additional laboratory facilities provided in the Research Center of Fairchild Tropical Garden by Jack B. Fisher are greatly appreciated.

³ pbtomlin{at}fas.harvard.edu

	LITERATURE CITED

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Behnke H.-D. S. Herrmann 1978 Fine structure and development of latificers in Gnetum gnemon L. Protoplasma 95: 371-384[CrossRef][ISI]

Behnke H.-D. G. S. Paliwal 1973 Ultrastructure of phloem and its development in Gnetum gnemon, with some observations on Ephedra campylopoda. Protoplasma 78: 305-319[CrossRef][ISI]

Carlquist S. 1994 Wood and bark anatomy of Gnetum gnemon. Botanical Journal of the Linnean Society 116: 203-211[CrossRef]

Carlquist S. 1996a Wood, bark and stem anatomy of New World species of Gnetum. Botanical Journal of the Linnean Society 120: 1-19[CrossRef]

Carlquist S. 1996b Wood and bark anatomy of lianoid Indo-Malesian and Asiatic species of Gnetum. Botanical Journal of the Linnean Society 121: 1-24[CrossRef]

Carlquist S. A. A. Robinson 1995 Wood and bark anatomy of the African species of Gnetum. Botanical Journal of the Linnean Society 118: 123-137[CrossRef]

Esau K. 1938 The multinucleate condition of fibers of tobacco. Hilgardia 11: 427-434

Esau K. 1943 Vascular differentiation in the vegetative shoot of Linum. III. The origin of the bast fibers. American Journal of Botany 30: 579-586[CrossRef][ISI]

Hallé F. R. A. A. Oldeman P. B. Tomlinson 1978 Tropical trees and forests: an architectural analysis. Springer Verlag, Berlin, Germany

Paliwal G. S. H. D. Behnke 1973 Light microscopic study of the organization of phloem in the stem of Gnetum gnemon. Phytomorphology 23: 183-193

Prodhan A. K. M. J. Ohtani R. Funada H. Abe K. Fukazawa 1995 Ultrastructural investigation of tension wood fibers in Fraxinus mandshurica Rupr. var. japonica Maxim. Annals of Botany (London) 75: 311-317[Abstract/Free Full Text]

Tomlinson P. B. 2001 Reaction tissues in Gnetum gnemon: a preliminary report. Journal of the International Association of Wood Anatomists 22: 401-413

Wilson B. F. R. R. Archer 1977 Reaction wood: induction and mechanical action. Annual Review of Plant Physiology 28: 23-43[ISI]

Zimmermann M. H. A. B. Wardrop P. B. Tomlinson 1964 Tension wood in aerial roots of Ficus benjamina L. Wood Science and Technology 2: 95-104

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