FASCIATION AND DICHOTOMOUS BRANCHING IN ECHINOCEREUS (CACTACEAE)

In Echinocereus reichenbachii dichotomous branching and fasciation (cresting) are rare events. Both were found together in only a few of many populations investigated and are interpreted as variants of a single phenomenon. They may occur at any stage of shoot development, but crest meristems arise most commonly on young branches among clusters of normal shoots. Sometimes they appear on unbranched young plants or seedlings, very rarely on older shoots. Dichotomy results from the division of an apical meristem into equal parts each of which functions independently, producing a forked shoot. Fasciation involves the extension of a single meristem into an apical ridge. The product is a flabellate shoot that becomes undulate if growth along the summit continues. In longisection linear meristems appear similar to radial sections of normal shoots; in median sagittal section they have a much extended central mother cell zone within which the cell pattern resembles a rib meristem. Although crest meristems become sluggish or even inactive with age, localized renewed growth may occur spontaneously or be induced by injury. In this species the random production of normal shoots from crest meristems (defasciation) was not observed, but if much or all of such a meristem is removed, branches may arise from lateral areoles, and these are always normal. It seems, therefore, that whatever induces fasciation in E. reichenbachii originates in and is restricted to the apical meristem and its immediate vicinity.     

DICHOTOMOUS BRANCHING IN MAMMILLARIA (CACTACEAE)

Cruciate dichotomous branching is a regular phenomenon in at least two species of cacti: Mammillaria perbella and M. parkinsonii, and there is exomorphic evidence that it occurs in other species of this genus. The specimens examined showed no obvious changes in the phyllotaxy of the two shanks derived by dichotomy. In the ecologically and morphologically specialized Cactaceae, it is quite unlikely that dichotomous branching represents the retention of a primitive character. It is furthermore improbable that it is of taxonomic value above the species level.     

罗汉果组织培养中愈伤组织和腋生枝的形成

用罗汉果茎段为外植体,培养在MS+BA1.0+IBA0.1毫克/升培养基上,诱导愈伤组织和芽形成。观察了罗汉果茎段愈伤组织的生长以及腋生枝的形成。罗汉果茎段培养5天后,潜伏腋芽开始萌动和生长。培养10天后罗汉果茎段的基部一端开始膨大。培养20天后产生大量白色疏松的愈伤组织,这时腋生枝已经长成3—6厘米长。培养30天后基部的愈伤组织中有少量瘤状小突起,但再分化形成芽的频率极低。结果表明,罗汉果茎段组培形成的苗均是从腋芽产生的。     

ABSCISSION AND THE AXILLARY FROND IN SPIRODELA OLIGORHIZA (LEMNACEAE)

Two abscission zones are present in fronds of Spirodela oligorhiza. In one zone the abscission layer separates the daughter frond and its connecting stalk from the mother frond. The second abscission layer separates the daughter frond from the connecting stalk. An axillary frond is asymmetrically positioned at the base of each daughter frond where it joins the mother frond. In right-handed physiological clones the axillary frond is to the right of the connecting stalk and in left-handed clones, to the left of the stalk. When a daughter frond abscises it leaves behind its axillary frond in the pocket of the mother frond. Histological features of abscission and treatments that induce abscission in Spirodela oligorhiza are described.     

EMBRYO STRUCTURE AND STORAGE RESERVE HISTOCHEMISTRY IN THE PALM WASHINGTONIA FILIFERA

The seed of Washingtonia filifera (Lindl.) Wendl. is hemispherical and has a smooth testa. The embryo is located on the rounded side of the seed near the raphe. The embryo consists of a prominent single cotyledon, an epicotyl, and a small root apex. The shoot apex is oriented at a right angle to the long axis of the embryo and possesses 2 to 3 leaf primordia. The cotyledon functions as a storage organ and is composed of three cell types with similar ultrastructure. These three types—the parenchyma, protoderm, and procambium—can be distinguished on the basis of position, size, and shape. The procambial strands in the cotyledon consist of a ring of bundles grouped into two distinct sympodia and extend from beneath the shoot apical meristem to the tip of the cotyledon where they are situated very close to the surface. The most prominent organelles within all cell types are protein bodies, lipid bodies, and crystalline protein fibers. The protein bodies contain small crystalline inclusions which are presumed to be phytin. Protein bodies in the protoderm were smaller, denser-staining, and contained fewer crystalline inclusions than those in the parenchyma or procambium. On a volume basis, the parenchyma was shown to be 43% protein bodies, 25% lipid bodies, 15% cytoplasm, 7% cell wall, 4% intercellular space, 2% nuclei, and 4% other organelles (mitochondria and plastids).     

独叶草叶二叉分枝脉序中网结脉和盲脉的形态学研究

对独叶草营养叶二叉分枝脉序及其中的网结脉和盲脉的形态学研究表明：(1)网结脉中2条完全汇合的与靠近脉中完全分离的叶脉之间未发现任何形式的维管束汇合的中间类型及网结脉中具有不同程度的连接脉退化痕迹的事实表明,网结脉不可能由靠近脉产生,相反,由于网结脉中联结脉的退化而形成开放脉;(2)盲脉是通过伴随着齿退化的达齿脉的退化、网结脉中联结脉的间断、非网结脉由分枝处间断三种方式产生的;(3)越裂片脉的出现及其可以形成网结脉的现象表明独叶草营养叶可能曾具有较为复杂的脉序,这种叶脉也呈现出退化的趋势;(4)独叶草营养叶的二叉分枝脉序可能是一种退化性状,而网结脉的出现可能是这种退化过程中的残留痕迹。     

SOME OBSERVATIONS ON BEHAVIOUR AND CALL IN THE PALM THRUSH CICHLADUSA ARQUATA

Boshoff, A. F. &; Vernon, C. J. 1980. The past and present distribution and status of the Cape Vulture in the Cape Province. Ostrich 51:230-250.

Because of the apparent decline in range and numbers of the Cape Vulture Gyps coprotheres in the Cape Province, the distribution and status of this species were reviewed according to four time periods from before 1905 to the present day. All available information was assembled, assessed and interpreted. It is apparent that, although the present decline is real, the population has undergone previous fluctuations. The magnitude, nature and possible causes of the fluctuations are discussed. It is postulated that the drastic decline in the game herds, particularly during the 19th century, together with the recent changes in stock farming, are the most important factors determining the numbers and distribution of Cape Vultures. Direct and indirect persecution also have a detrimental effect on vulture populations. Farmers' attitudes towards vultures are mentioned and conservation priorities and problems are listed.     

ENDOSPERM STRUCTURE AND STORAGE RESERVE HISTOCHEMISTRY IN THE PALM,WASHINGTONIA FILIFERA

The endosperm of Washingtonia filifera consists of living cells with the same general cellular structure throughout the seed. The major storage reserves are carbohydrate, stored in the form of thickened walls; lipid, stored as numerous small lipid bodies which fill the cytoplasm; and protein, stored as large, but variably-sized, protein bodies. The protein bodies contain two types of inclusions: prismatically-shaped denser protein crystalloids and small crystalline deposits presumed to be phytic acid. The X-ray microanalysis shows these crystalline inclusions do contain P, Ca, Mg, and Fe. Protein bodies are positively stained with PAS. Nuclei are present in all cells, but stain very palely. Plastids and mitochondria are present, but infrequently seen. The plastids have few, poorly developed membranes. Endoplsasmic reticulum and dictyosomes are lacking. The cell wall is thick except in areas of pit fields and consists of three layers which differ in their staining with toluidine blue and in their ultrastructural characteristics: middle lamella, thickened outer wall, and thin inner wall. All wall layers are positively stained with PAS and calcofluor. Although general structural features of the endosperm in Washingtonia filifera are similar to those in date seeds, the composition of the wall polysaccharides and protein bodies appear to differ somewhat.     

MORPHOLOGY AND DICHOTOMOUS VASCULATURE OF THE LEAF OF KINGDONIA UNIFLORA

Foster , Adriance S. (U. California, Berkeley), and Howard J. Arnott . Morphology and dichotomous vasculature of the leaf of Kingdonia uniflora. Amer. Jour. Bot. 47 (8): 684–698. Illus. 1960.—An intensive study of the nodal anatomy, petiolar vasculature and open dichotomous venation of the leaf of Kingdonia has revealed a type of foliar vascular system of unusual morphological and phylogenetic interest. The vascular supply at the nodal level consists of 4 collateral traces which diverge from a single gap into the sheathing leaf base. This type of nodal anatomy is perhaps primitive, and comparisons are made with the unilacunar nodes and the 2- and 4-parted leaf trace systems characteristic of many angiospermous cotyledons and the foliage leaves of certain woody ranalian genera. The petiole of Kingdonia is vascularized by 2 pairs of bundles which represent the upward continuation of the 4 leaf traces. A transition from an even (4) to an odd (3) number of strands occurs near the point of attachment of the 5, lobed, cuneiform lamina segments to the petiole. Each of the 2 abaxial bundles dichotomizes and the central derivative branches fuse to form a double bundle which enters the base of the median lamina segment. The 2 adaxial petiolar bundles diverge right and left into the bases of the paired lateral segments of the lamina. An analogous type of transition from an even to an odd number of veins occurs in many angiospermous cotyledons which develop a definable mid-vein. But, in Kingdonia, the bundles which enter the bases of the lamina segments give rise to systems of dichotomizing veinlets devoid of “mid-veins.” Although the majority of the terminal veinlets enter the marginal teeth of the lamina segments, “blind” endings, unrelated to the dentations, occur in all the leaves studied. Typically, all of the vein endings in a given lobule of a lamina segment are derived from the same dichotomous vein system. However, in some leaves, a veinlet dichotomizes directly below a sinus and the branches diverge into the marginal regions of 2 separate lobules. The phylogenetic significance of the occurrence of open dichotomous venation in such an herbaceous angiosperm as Kingdonia is briefly discussed. From a purely morphological viewpoint, the Kingdonia type of venation invites direct comparison with the venation of Sphenophyllum, certain ferns or Ginkgo rather than with any of the known reticulate venation patterns of modern angiosperms. Although the foliar venation of Kingdonia may represent the result of evolutionary reversion, the very rare anastomoses which occur seem primitive in type rather than “vestiges” of a former system of closed venation.     

ONTOGENY OF THE OPEN DICHOTOMOUS VENATION IN THE PINNA OF THE FERN NEPHROLEPIS

Pray , Thomas r . (U. South. California, Los Angeles.) Ontogeny of the open dichotomous venation in the pinna of the fern Nephrolepis. Amer. Jour. Bot. 47(5) : 319—328. Illus. 1960.–The venation of the pinna of Nephrolepis consists of a midvein and 2 lateral series of dichotomizing veins all of which terminate freely near the margins. The development of the pinna is analyzed with particular attention to the nature of the marginal meristem and the organization of the embryonic pinna as it appears in paradermal section. The arrangement of cells in pinna wings during the period of marginal growth displays a pattern which foreshadows the pattern of the mature venation. In contrast with the development of the leaves of angiosperms, marginal growth continues into a relatively late phase of pinna ontogeny and apparently is active throughout the phases of ontogeny concerned with blocking-out the pathways of procambial differentiation. Thus the pattern of venation appears to be correlated with the manner of activity of the marginal meristem and subsequent orientation of its derivatives. The theoretical aspects of the result of this investigation are discussed in relation to other studies of foliar venation ontogeny.