Research Journal of Recent Sciences ______ ______________________________ ______ ____ ___ ISSN 2277 - 2502 Vol. 1( 5 ), 28 - 37 , Ma y (201 2 ) Res.J. Recent Sci. International Science Congress Association 28 Distribution and P attern of availability of S torage starch and cell death of R ay parenchyma cells of a C onifer T ree ( Larix kaempferi ) Islam M. A . 1,3, *, Begum S . 2,3 , Nakaba S . 3 , and Funada R . 3 1 Graduate Training Institute, Bangladesh Agricultural University, BANGLADESH 2 Department of Crop Botany, Faculty of Agriculture, Bangladesh Agricultural University, BANGLADESH 3 Faculty of Agriculture, Tokyo University of Agriculture and Technology, JAPAN Available online at: www.isca.in (Received 2 9 th Febr uary 2012 , revised 6 th March 2012 , accepted 1 9 th March 2012 ) Abstract Starch in the ray parenchyma cells of Larix kaempferi tree varies considerably on the position of trunk. The maximum starch granules observed in sapwood, mostly outer to middle part. Most starch grains were localized in middle lines of parenchyma cells rat her than upper and lower lines. Parenchyma cells of the phloem part also content starch rather than outer bark due to content dead cell almost. The distribution of nuclei in secondary xylem cells of L. kaempferi resembled cell death. Starch disappearing oc curred prior to cell death in secondary xylem cells. Some characteristics heartwood inducing substances synthesized just after starch depletion, which might be deposited in cell wall. Ray parenchyma cells remained alive for several years. The timing of cel l death of middle ray cells different from upper and lower radial ray cells within a ray. Our results also indicate that the position of starch depletion within a ray might affect the timing of cell death. The distribut ion pattern of storage starch and cel l death was inter - linked with each other. This relationship controls the formation of heartwood in conifer trees. This report would be helpful for further research to clarify the heartwood formation in conifers, which has importance in tree breeding progra m and improvement of quality wood. Keywords: Larix kaempferi , s torage materials, r ay parenchyma cell, c onifer, h eartwood formation. I ntroduction Starch is a major reserve product of trees, and accumulates particularly in ray cells of the xylem and cambium. Ray parenchyma cells remain alive for several years at least, and they play an important role in the storage and transport of nutrients 1, 2 . During transporting of such nutrients the amount varied on position of tissue and annual ring. The reserve material s (e.g. starch) have been removed or converted into heartwood substances 3 . Some species form colored heartwood because xylem parenchyma cells synthesize heartwood substances such as polyphenols that contribute to increases in the decay resistance of tree t runk, prior to their death 4 - 7 . Cell death plays important roles in the function of secondary xylem cells in woody plants. Tracheary elements lose their organelles immediately after their differentiation 8 and after cell death; tracheary elements play a critical role in the transport of water. The early death of ray parenchyma cells within upper and lower cell lines of a ray has been observed in hardwoods, such as Magnolia obovata and Populus tremuloides 9 . One research group observed the positional differences in the quantities of starch grains among ray parenchyma cells in the quantities of starch grains among ray parenchyma cells in some hardwoods, such as Castanea crenata 10 . Therefore, we postulated that positional informat ion might be an important determinant of the control of cell death, differentiation and function of ray parenchyma cells in hardwoods, as is the case in conifers. The significance of differences in elemental distribution between sapwood (SW) and heartwoo d (HW) is still unclear. Since the complex process of formation of heartwood from sapwood consists of a chain of events involving many activities so that our present study will find out such information of storage substances, their occurrences and degradat ion among the different parts of ray parenchyma cells, which would be a part of one activity 8,11 . In this article we demonstrate th e chronological steps of starch appearance and their degradation patterns within the ray parenchyma cells. The distribution o f starch among the sapwood - heartwood of L. kaempferi is discussed from a histochemical viewpoint. This report contributes to the understanding of the physiological changes associated with the senescence of ray parenchyma cells and storage starch distributi on . A comparison study on the disappearing pattern of storage starch and nuclei within cells was made. However, the detailed mechanism of histochemical changes in transition zone from sapwood to heartwood is remaining limited. Therefore, in the present stu dy, we investigated histochemical changes of starch from sapwood to heartwood in Japanese larch ( Larix kaempferi ) tree to make a clear conception about the mechanism of cell death in transition zone and heartwood formation. Material and Methods Plant mate rials : A Japanese larch ( Larix kaempferi ) trees of approximately 1 6 years of age, grown at tree breeding center, Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 29 F FPRI (Forestry and Forest Products Research Institute), Nag ano prefecture, Japan used in this study. Discs from stem trunk (at breast height) were collected just after felling the tree in May 2011 (season of active cambium). Samples were fixed in 4% glutaraldehyde in 0.1M phosphate buffer (pH 7.3) at room temperature . Preparation of samples for observation of starch : Fixed samples were washed in distilled water followed by trimming into small pieces and, sections (radial, transverse, and tangential) were cut at a thickness of approx. 40 µm with a stainless steel mic rotome blade on the freezing stage of a sliding microtome (MA - 101; Komatsu Electronics, Tokyo, Japan) and washed with phosphate - buffered saline (PBS; 137mM NaCl, 2.7 mM KCl, 1.5 mM KH 2 PO 4 , 8.0 mM NaHPO 4 , adjusted to pH 7.3) 11 . For light microscopic observa tions of starch grains, sections were stained with iodine - potassium iodide (I 2 - KI) for 2 - 3 min 11 - 14 . After staining, sections were washed with distilled water. Semi - quantitative analysis of starch and brown unknown materials : For the semi - quantification of starch , the desired portion of phloem, cambium, and xylem ray parenchyma cells were cut from the original images. Each category of cells in the image was segmented by manually drawing an outline, and the images were converted to binary im ages. The total analyzed - section area and total starch grains area were measured with the particle analysis command of Image J. The percentage of starch for specific area was calculated for each xylem ray parenchyma cells 14 . According to the above mentione d method the semi - quantification of unknown brown colored substances were done. Preparation of samples for observation of nuclei : After cutting the sections using sliding microtome (as above), sections were stained with 1% aqueous solution of acetocarmine followed by washi ng with distilled water and series of ethanol (from 30% to 100% ethanol) for observation of nuclei 11 - 12 . Stained sections were observed under a light microscope (Axioscop; Carl Zeiss, Oberkochen, Germany). For observation of the autofluor escence of nuclei, radial sections of 40 µm thickness were examined with a fluorescence microscope (BX61; Olympus, Tokyo, Japan) under epifluorescence illumination (excitation/emission combination, BP 460 - 495/BA 510IF) 12 . Result s and Discussion The color of the heartwood of L. kaempferi was dark brown and the sapwood was light yellowish. The sapwood - heartwood (SW - HW) boundary occurred between mid of 7 th and latewood of 8 th annual ring ( figures 1a, b) from the cambium . Gradually the color of the sapwood changed to dark yellowish to light brown in the heartwood. Transition zone occurred in between sapwood and heartwood region ( figure 1b). Some morphological basic labeling and different angular anatomical views were shown schematic ally in figure 1c. In case of our study, only radial surface of the sample was examined. Fig ure - 1 Photographs (a and b) and sketch diagram (c) showing morphological views of Larix kaempferi by naked eye. a) a collected stem disc, b) enlarged view of a part of stem disc; c) different parts of a stem disc showing with different angular views. SW, sapwood ; TZ, transition; HW , heartwood Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 30 The distribution of reserve starch was observed in the trunk wood of L. kaem feri . The starch granules were observed as black mass and black grain like structure under light microscope. Visualization of starch covered from phloem to heartwood of the sample. There was no remarkable starch found in phloem and cambial zone. Limited st arch grains viewed within phloem parenchyma cells, but not in uniform distribution ( figure 2a). Our observation also revealed that there was complete lack of starch in current year xylem ( figure 2a) and second year xylem from the cambium (data not shown). From third annual ring to inner sapwood the starch granules increased with depth. The abundant starch granules visualized in mid early wood of 7 th annual ring ( figure 2b). There were numerous heterogeneous brown colored materials appeared in ray parenchyma cells of 3 rd growth ring to inside of trunk ( figure 2b). The complete depletion of starch observed in 8 th growth ring counted from the cambial zone ( figure 2c). To investigate the sources of brown colored unknown substance, we observed a similar section with and without I 2 - KI staining. Results on such investigation showed the brown colored unknown substances appeared in both sections. So, the or igin of such materials not comes from stain. Only brown materials visualized in control observation ( figure 3a). On the other hand, both starch and brown materials available in ray parenchyma cells together ( figure 3b). So, there was no change of brown col ored materials observed after I 2 - KI reaction. Beside those, the distribution pattern of storage starch within different parts of an annual ring was investigated, which depicted in figure 4. The outer early and mid of the early wood showed maximum depositio n of starch in ray parenchyma cells of an annual ring ( figure 4a), but decreasing the starch deposition at the innermost early wood portion ( figure 4b). On the other hand, there was complete devoid of starch occurred in ray parenchyma cells of latewood pot ion in an annual ring ( figure 4b). Fig ure - 2 Light micrographs of radial sections, stained with iodine potassium iodide showing starch grains around the phloem - cambium zone (a) , sapwood (b) and heartwood (c) of Larix kaempferi stem . Ph, Phloem ; Cz, Cambial zone ; Xy, Xylem ; a rrows indicate starch grains ; arrowheads indicate unknown brown colored materials Fig ure - 3 Comparison of light micrographs between before (a) and after (b) staining with iodine potassium iodide in sapwood (around middle of 6 th annual ring from cambium) of Larix kaempferi stem . White arrowheads indicate brown colored materials , red arrowheads indicate starch grains; xrp, xylem ray parenchyma cell; t, tracheid. Scale bars = 50 µm Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 31 Fig ure - 4 Light micrographs of radial sections of ray parenchyma cells of Larix kaempferi , showing distribution pattern of starch grains within an annual ring (from outer early wood of 6 th annual ring to latewood of 7 th annual ring). Sections stained with iodine pot assium iodide to localize starch grains. a) abundant of storage starch grains (white arrowheads) visualized from outer early wood (OEW) to mid early wood, b) innermost early wood (IEW) region of 6 th annual ring showing starch grains (white arrowheads) and latewood (LW) region of 7 th annual ring showed lack of starch (black arrowheads) in cells Semi - quantification of starch and brown colored materials were examined in relation to different parts of sample. In starch quantification, the maximum occurrence observed in 7 th annual ring, i.e. innermost part of sapwood ( figure 5). Whereas the starch content was nil in phloem, cambial zone, 1 st and 2 nd annual ring (counted from the cambium). The quantity of starch showed increasing tendency fro m 3 rd annual ring to 7 th , dramatically it was also nil in 8 th annual ring ( figure 5). On the other hand, quantity of unknown brown colored substance showed relationship with starch appearance and depletion. Data showed the increasing tendency appeared from 6 th to 7 th annual ring, where maximum starch content abruptly depleted. This sud den depletion of starch may cause of increasing the amount of brown colored substances ( figure 5). Rather than the all over parts from phloem to heartwood, we also investigated semi - quantification among different portions of 7 th annual ring. Our findings r eported the outer xylem ray parenchyma showed increasing tendency up to the mid early wood, but the degradation also appeared dramatically from mid early to inside of 7 th annual ring ( figure 6). The degradation pattern is very quickly occurred, where the q uantity of brown colored materials extremely higher ( figure 6). In the 7 th annual ring the tendency of the amount of brown colored materials increased slowly before the middle early wood, then suddenly reached higher peak just after depletion of starch ( fi gure 6). The h ighest availability of starch can be observed in the mid of 7 th annual ring ( figure 6 ) and decreases with increasing depth into the trunk and ceases at the sapwood - heartwood boundary. A marked decrease in starch content occurred during transf ormation of sapwood into heartwood. This zone is located between mid and innermost part of 7 th annual ring. In the outer heartwood no trace amount of starch were present ( figure 6 ). Fig ure - 5 Line graphs showing percentage of starch and brown colored substances in ray parenchyma cells of different portion of Larix kaempferi stem. Ph, phloem; Cz, cambial zone; AR, annual ring . Annual ring numbers were counted from the cambial zone. Vertical bars indicate standard errors Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 32 Fig ure – 6 Line graphs showing percentage of starch and brown colored materials in xylem ray parenchyma cells of different portion of 7 th annual ring of Larix kaempferi stem. AR7 - 1 to AR7 - 7 indicates the sequential parts of xylem ray parenchyma cells within the 7 th annual ring. Annual ring counted from the cambial zone. Vertical bars indicate standard errors Nuclei observation was illu strated in figure 7 . The shape and size of nuclei vary with location and types of cell. By using acetocarmine stain, the nuclei of live cells became red colored. The outer phloem cells were devoid of nuclei since those cells dead ( figure 7a). The live cell s in inner bark tissue content relatively small sized nuclei. Elliptical shaped nuclei visualized in phloem parenchyma cells observed ( figure 7b). Cells of cambial zone content round shaped nuclei ( figure 7c). Ray parenchyma cells in middle sapwood content various shaped nuclei ( figures 7c - e). Nuclei were not visualized in the heartwood cells, i.e. dead cells ( figure 7f). The variation of the shape of nuclei clearly visualized between early wood and latewood under fluorescence microscope ( figure 8). Usually fusiform shaped nuclei visualized in early wood portion of the xylem tissue. The small and spherical shaped nuclei noticed in latewood portion of xylem tissue. This difference occurred due to the size of ray parenchyma cells or species specific genetical factors. Rather than the differences between latewood and early wood of xylem, the size and shape of nuclei also varied due to different physiological factors which are demonstrated in figure 9. Fig ure - 7 Light micrographs of radial observation of nuclei of different parts of stem of Larix kaempferi , s tained with acetocarmine. a) phloem tissue , b) phloem ray parenchyma cells , c) ray parenchyma cells of camial zone and current year xylem, d) Slender nuclei i n ray parenchyma cells of mid sapwood, e) ray parenchyma cells in early wood of 5th annual ring, f) heartwood zone, ray parenchyma cells devoid of nuclei. Arrowheads indicate nuclei within cells; ob, outer bark; ib, inner bark; cz, cambial zone. Scale bars 50 µm Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 33 Fig ure – 8 Illustration o n nuclei between early wood and latewood of an annual ring of Larix kaempferi stem under epifluorescence illumination (excitation/emission combination, BP 460 - 495/BA 510IF). EW, early wood; LW, latewood; arrows indicate boundary between 6 th and 7 th annual ring, counted from cambium; arrowheads indicate nuclei in ray parenchyma cells Nuclei visualized up to the middle of 7 th annual ring uniformly, and then d isintegration of nuclei observed up to latewood of 8 th growth ring in L. kaempferi . There were some morphological changes in nuclei observed in xylem ray parenchyma cells. All ray parenchyma cells from the phloem to cambial zone, had spherical nuclei, rela tively smaller spherical shaped nuclei observed in current year xylem. Mostly fusiform and spherical nuclei visualized from 2 nd annual ring to inner region of 7 th annual ring, rather than variation of size between latewood and early wood. Deformed and rela tively smaller sized nuclei visualized from innermost region of 7 th annual ring to latewood of 8 th annual ring ( figure 9 ). There were varieties of shape and size remarked in sapwood, intermediate portion between sapwood and heartwood. Xylem parenchyma cells of same species showed morphologically distinguished nuclei shape ( figures 9a, b). The remarkable slenderness of nuclei in ray parenchyma cells of middle sapwood observed, which was not found in sapwood near to cambial zone ( figure 9b). The nuclei be come smaller and distorted into abnormal shapes just before their disappearance ( figure 9c), which is observed in transition area between sapwood and heartwood of L. kaempferi stem. Most of the nuclei were not visualized under light microscope due to prese nce of unknown substance in the transition area ( figure 9d). The different shape and size of nuclei in parenchyma cells of a ray of an individual annual ring were noticed in this investigation also. The schematic representation on the distribution and pat tern of starch and nuclei was illustrated in figure 10. Nuclei were uniformed visualized from phloem to 6 th annual ring. Nuclei of mid of 7 th annual ring also visualized uniformly within the cells in outer part ( figure 10 ) rather than one or two cells beco me dead (i.e. lack of nuclei) in inner part . Nuclei disappearing or losing started from the boundary area between sapwood and heartwood , which located from innermost part of 7 th to latewood part of 8 th growth ring . There was no nucleus present in heartwood region, i.e. after latewood of 8 th annual ring ( figure 10 ). The localization result revealed that starch depletion within the ray parenchyma cells occurred prior to the death of cells. No living cells were found in the heartwood zone. There are numerous h eterogeneous unknown substances observed in SW - HW boundary followed by disappearing starch droplets ( figure 10 ). It indicated the formation of such unknown substances may be the results of starch degradation. The live and dead cells were also easily distinguished in the schematic diagram ( figure 10) . The brown colored substances visualized from 4 th growth ring to inside (i.e. outer xylem part ) . The occurrence of such substances increased with the inside of xylem tissue towards the transition zone ( figure 10) . In heartwood region, the absence of such brown substances is remarkable ( figure 10 ). Such kind of substances may be intermediate products to induce heartwood, which may be produced from storag e starch within the cells. The remarkable cell wall thickening also characterized between current year xylem ( figure 10a) and innermost part of 7 th annual ring ( figure 10b). Thus, brown colored substances might play an important role in the formation of he artwood or heartwood inducing substances and the transport of such materials that are related to cell death. The differences in terms of the timing of cell death, differentiation and appearance of storage starch in ra y parenchyma cells of L. kaempferi were schematically shown also in figure 10. The positional patterns of disappearance and overall distribution of storage starch a lso illustrated there. No considerable amount of starch grains visualized in phloem, cambial zone and outermost xylem ray parenchyma cells. There were abundant storage starch observed from 4 th to middle part of 7 th growth ring, after that no starch was found inside the trunk. The distribution patterns and the quantitative variation of storage mat erials among the annual ring s of Larix kaempferi demonstrated in figure 10. Results revealed that distribution patterns indicate a characteristic features, which would be more important to study the physiology as well as heartwood Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 34 formation . Quantitatively, storage starch increased with the depth of annual ring from the cambium zone, where outermost 2 annual rings showed almost devoid of storage starch. The increasing tendency observed with the depth of xylem tissue up to their final degrada tion. This degradation directly emphasized on the part for synthesis of unknown brown substances ( figure 10). The overall starch disappearing zone, increasing tendency of brown colored substances and their depletion in xylem ray parenchy ma cell were outlined in figure 11. In short, the different zone between 7 th and 8 th growth ring and the localization of starch, brown colored materials, and nuclei in relation to sapwood, heartwood and their intermediate zone (i.e. transition zone) were i llustrated at a glance. Furthermore, we also observed differences in the timing of ray parenchyma cell death ( figure 11 ). All of the cells started to die from inner region of 7 th annual ring to latewood of 8 th annual ring (from the cambium). The appearanc e of unknown brown colored substances enormously increased by the mid of 7 th annual ring just after disappearing of storage materials ( figure 11 ). In heartwood portion (from latewood of 8 th to inward of trunk), such brown unknown substances are deposited i nto the cell wall, followed by natural color of the cells become darker than outer sapwood. Fig ure - 9 Light microscopic features of nuclei in ray parenchyma cells of different parts of Larix kaempferi stem ; a) cells of sapwood, mid of 7 th annual ring, b) outer sapwood region (7 th annual ring from the cambium), c) intermediate/transition zone between sapwood and heartwood (latewood region of the 8 th annual ring from cambium) , arrowheads indicate dead cells , d ) mid 7 th annual ring zone. Scale bars 50 µm Fig ure - 10 Diagram on distribution patterns of storage starch and nuclei in ray parenchyma cells of Larix kaempferi stem. Ph, Phloem; Cz, Cambial zone; CYX, Current year xylem; YX, year xylem (e.g. 6YX indicates 6 th year xylem ) ; a, narrower cell wall in current year xylem; b, thickening of cell wall in innermost early wood of 7 th annual ring. Annual rings counted from cambial zone Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 35 Fig ure – 11 Outline view on distribution of starch, nuclei and brown colored substances in respect of sapwood, transition zone and heartwood between 7 th and 8 th annual ring of Larix kaempferi stem . Horizontal and vertical bars indicate distribution and limit of such observation. Scale bar 100 µm Discussion It is well known that some of photosynthates move inward from the inner bark through the rays to the cambium. Rest of the photosynthates after consumed for different physiological functions, moving along the rays toward the Fra nces J Sharom center of the tree. Some of them may begin to accumulate and over time begin to break down to form a variety of compounds collectively as extractives. In a living tree most of the sapwood cells are dead (i.e., lack of protoplast); they live, on average, only about three week s after they are formed. The food storage cells, however, live for a much longer time, and it is the death of these cells that marks the formation of heartwood. The patterns of cell death and distribution pattern of storage substances in the secondary xyle m play an important role in the functions of heartwood formation. Most wood cells die after differentiation and cell wall lignifications. Only ray parenchyma and resin canal epithelial cells remain alive. However, starting from the cambium, and proceeding to inner sapwood, a gradual degradation of the cytoplasm in parenchyma cells occurs. During heartwood formation extractives are gathered in the cell walls and, eventually, even ray parenchyma cells die 1 5 - 1 6 . Wall thickening and lignifications of the ray pa renchyma cells 9, 1 7 and also the radial resin canal tissue have been reported to be closely associated with the heartwood formation in the genus Pinus 1 8 . Hydrolysis of storage starch could partly account for the larger amount of unknown brown colored sub stances, synthesized through entire sapwood, because the amount of storage materials decreased towards the transition zone, while the heartwood extractives increased ( figures 9, 10). Although previous reports could be easily assumed that heartwood extracti ves are responsible due to their color and exclusive existence in the formation of heartwood. Using UV - visible microscopic spectrometry, a research work reported that these materials had absorption in the UV range, indicating that they were heartwood pheno lics 19 . Therefore, it was suggested that ray parenchyma cells could biosynthesize and accumulate different kinds of heartwood extractives. It has been reported that both axial and ray parenchyma cells are involved in heartwood formation with their differen t functions 2 0 - 2 1 . Our observations revealed that heartwood extractives were formed in situ at the heartwood periphery from translocated starch . The starch granules were degraded mostly at the sapwood - heartwood transition zone 2 2 . The composition of the subs tances formed is under genetic control and the amount formed is significantly influenced by the physiological conditions impinging on the parenchyma at the time of formation. In Robinia pseudoacacia (black locust), as in other heartwood forming species, th e transition zone between sapwood and heartwood shows an enhanced metabolic activity at certain times of the vegetation period 2 3 - 2 5 . The formation and accumulation of heartwood inducing substances related with the transformation of sapwood into heartwood, and it is attractive to speculate that the building blocks of these secondary substances derive from storage starch. One of the past research report was the best evidence to supports that the polyphenols are formed in situ from the carbohydrates in the dy ing sapwood cells 2 6 . Our result suggested such unknown brown colored heterogeneous substances either partly or fully responsible for heartwood formation. Those substances enormously increased followed by disappearing of starch grains ( figures 4, 9, 10 ). The differences in timing pattern of the disappearance of starch suggested different roles for directly synthesis of unknown brown colored heterogeneous substances within ray parenchyma cells, which play an important role to form heartwood inducing substan ces or directly to form heartwood. In present study, we investigated the disappearance of nuclei as an indicator of cell death of ray parenchyma cells. The partial disappearance of nuclei from ray parenchyma cells started from the upper or lower radial c ell lines of each ray 11 - 12, 27 - 28 . Similarly, in Larix kaempferi, cell death of ray parenchyma cells in the upper and lower cell lines occurred earlier than that of ray parenchyma cells that were located within the other cell lines ( figure 9). Those observ ations revealed that different positions Research Journal of Recent Sciences ______ ______ _ _ _______________________________ ______________ __ ISSN 22 77 - 2502 Vol. 1(5), 28 - 3 7, May (2011) Res.J. Recent Sci. International Science Congress Association 36 within a ray are associated with differences in the timing of cell death of ray parenchyma cells in conifers. By contrast, ray parenchyma cells remained alive with protoplasm from the sapwood to intermediate wood. R esearch on Acacia auriculiformis indicated that nuclear slenderness ration increased in ray cells contiguous to vessels but gradually decreased in ray cells away from vessels 27 . In this study, nuclear slenderness clearly observed in ray parenchyma cells of L. kaempferi from the cambial zone to transition zone of sapwood - heartwood region . Ray parenchyma cells could survive for at least 7 years, i.e. the growth time from cambium zone towards intermediate wood in L. kaempferi . The disappearance of nuclei was a signal of the death of ray parenchyma which marked the formation of heartwood. Our study revealed, st arch grains were localized in ray parenchyma cells of outer sapwood of L. kaempferi . Most of the starch grains found in the middle ray parenchyma cells ( figures 2, 3 ). The disappearing pattern of starch within ray cells is observed in a pattern, which related to timing of cell death. In a previous report 11 , the position with ray might be an important factor in the control of timing of cell death, the patt ern of differentiation and function of ray parenchyma cells in conifer, A. sachalinensis . In present study, we found evidence that position of starch availability, chronological changes of quantity, pattern of disappearing within a ray might be affect cell death and deposition of heartwood substance within the cell wall in Larix kaempferi . The order of disappearance of studied storage starch corresponded to that of cell death among the ray parenchyma cells around the sapwood - heartwood region of L. kaempferi . It also reported that the disappearance of starch related to the various parenchyma cell deaths of Robinia pseudoacacia L var. inermis 28 . Therefore, information on the distributing pattern studied storage materials appears to be an important factor in the disappearing of cell contents, regulation of cell death, ultimate formation of heartwood. Investigations on the nature and radial distri bution of reserve materials showed that in general the outer sapwood contains relatively higher amount of starch , while the heartwood is almost free of such storage materials. This is valid for soft - and hardwood species 24,29 . It has been suggested that pr ecursors of heartwood constituents are translocated via the rays of the site of their synthesis 5 . In any case, storage s tarch in the living cells of sapwood must play a crucial role in the synthesis of heartwood constituents. We conclude that the substrate s for the synthesis of heartwood compounds derived in part from the breakdown of starch. A translocation of heartwood extractives via the phloem and the rays to sites of accumulation at the sapwood - heartwood boundary seems to be unlikely. Histochemical parameters in terms of starch and nuclei have been studied intensively in our reports. Considerable histochemical variations and their patterns of disappearance have been noticed during transition from the sapwood to the heartwood. This study emphasized on the further works on the analysis of sapwood, heartwood and their transition zone to understand the biochemical mechanism involved in the heartwood formation. It also serves some physiological findings between starch and nuclei which might be involved dir ectly and /or indirectly in the formation of heartwood in conifers. Conclusion The starch contents from outer sapwood to inner sapwood and their gradual degradation from inner sapwood to outer heartwood suggesting that heartwood extractives are formed par tly by hydrolysis of starch. The decrease in the amount of starch with the depth of the heartwood indicating reduced vitality and membrane deterioration of the xylem ray parenchyma cells in the heartwood portion. It also affects on the cell death, which is one important feature of heartwood. Abrupt increase of unknown brown colored substances just after depletion of starch indicates the raw materials supplied from degraded starch. Those substances deposited in cell wall, that’s why the thickening of cell wa ll observed after formation of such brown colored substances. Moreover, the differences of starch localization and disintegration from sapwood to heartwood and availability of unknown materials that was observed in this study, would give information for fu rther research regarding heartwood formation in conifers. This research would be helpful for further physiological works to improve wood quality. References 1. 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