Communities Adjust their Temperature Optima by Shifting Producer-to-Consumer Ratio, Shown in Lichens as Models: II. Experimental Verification

The community adaptation hypothesis [7] predicts that lichens, simple communities of microorganisms, can adapt to a wide range of thermal regimes by regulating the ratio of primary producers (algae) and consumers (fungi): R_p/c. To test this hypothesis, we determined R_p/c values by image analysis of cross sections of herbarium specimens of the lichen Cladina rangiferina, which is widely distributed between the Arctic and the tropics. We found that R_p/c for C. rangiferina increases with summer temperature by more than one order of magnitude, consistent with the hypothesis. To assess the ecological significance of community adaptation (R_p/c regulation), other adaptive mechanisms (e.g., photobiont substitution, genetic adaptation, and photosynthetic acclimation in North American Cladina spp.) were studied. Laboratory investigations with algae and fungi isolated in culture from live specimens suggested that the role of these mechanisms is relatively minor and cannot account for the high degree of lichen adaptability.     

Non-destructive species identification of Drosophila obscura and D. subobscura (Diptera) using near-infrared spectroscopy

The vinegar flies Drosophila subobscura and D. obscura frequently serve as study organisms for evolutionary biology. Their high morphological similarity renders traditional species determination difficult, especially when living specimens for setting up laboratory populations need to be identified. Here we test the usefulness of cuticular chemical profiles collected via the non-invasive method near-infrared spectroscopy for discriminating live individuals of the two species. We find a classification success for wild-caught specimens of 85%. The species specificity of the chemical profiles persists in laboratory offspring (87–92% success). Thus, we conclude that the cuticular chemistry is genetically determined, despite changes in the cuticular fingerprints, which we interpret as due to laboratory adaptation, genetic drift and/or diet changes. However, because of these changes, laboratory-reared specimens should not be used to predict the species-membership of wild-caught individuals, and vice versa. Finally, we demonstrate that by applying an appropriate cut-off value for interpreting the prediction values, the classification success can be immensely improved (to up to 99%), albeit at the cost of excluding a considerable portion of specimens from identification.     

A morphometric study of limb proportions in leaping prosimians

Study of individual limb proportions—most notably, for instance, of the intermembral index—distinguishes from most other primates those various prosimians capable of leaping. The present investigation analyzes 24 measures of limb proportions (taken by F.-K. Jouffroy and J. Lessertisseur) from 161 specimens representing 12 species of prosimians, using the multivariate statistical method of multiple discriminant analysis (carried out by R. German and C.E. Oxnard). The results indicate that there are three major gradients: (1) indriids, (2) cheirogaleines, and (3) galagines plus Tarsius, radiating from a fourth centrally located group of species, Lemur, Lepilemur, and Hapalemur. It is likely that the morphometric relationships displayed here can be associated with behavioral (locomotor) parallels among these various forms. Though leaping is a most important adaptation among prosimians, it seems clear that it has evolved separately a number of times, and it seems at least likely that the biomechanical nature of the adaptation differs in different groups. The results, therefore, present certain new hypotheses about prosimian locomotion that can only be tested with further field and laboratory studies. This study also emphasizes the fact that anatomical adaptation is complex. Though the analysis of each anatomical region separately provides a similar qualitative picture of the variation among genera, it is only in the analysis of all measures taken together that the complete pattern described above appears. Though no new variables have been added in that analysis, new information is obviously contained within the results. Since this information stems from the interactions of the variables, it must be due to associations between these anatomical areas.     

Morphological adaptation of shape to flow: Microcurrents around lotic macroinvertebrates with known Reynolds numbers at quasi-natural flow conditions

Summary Using Laser Doppler Anemometry we measured current velocities in the median plane around dead lotic macroinvertebrates in a flume which reproduced natural near bottom hydraulics. We investigated specimens of the gastropods Ancylus, Acroloxus, and Potamopyrgus, the amphipod Gammarus, and the larval caddisflies Anabolia, Micrasema, and Silo of various size, various alignment to the flow or which were otherwise manipulated in order to clarify certain questions of adaptation of shape or case building style to flow, or the effects of flow on field distribution patterns. The steepest velocity gradients close to the animals were found near areas of their bodies protruding furthest into the flow. In such regions the rates of potential diffusive exchange processes, the potential corrasion (abrasion through suspended solids), and, for larger specimens, the lift forces (directed towards the water surface) must be highest. Posterior of these areas growing boundary layers formed above those species whose upper contour was approximately parallel to the upstream-downstream direction of the flow. All specimens removed momentum from the flow and thus experience a drag force (directed downstream). From the complete data set we derived the following general conclusions about the physical effects of potential morphological adaptations, taking into consideration diffusion through boundary layers, corrasion, lift forces, friction and pressure drag forces: The physical significance of these five factors generally depends on the Reynolds number of an animal and is largely affected by flow separation, which was significantly related to the ratio of body length to height and the slope of the posterior contour. A simultaneous effective morphological adaptation to all five factors is physically impossible and, in addition, would have to change from life at low (e.g. a young, small specimen of a species) to life at high (e.g. a fully grown specimen of the same species) Reynolds number.     

The spectral sensitivity of a littoral annelid:Nereis mediator

Summary The spectral sensitivities of the four eyes ofNereis mediator (Polychaeta, Annelida) were measured from 400 nm to 600 nm by determining the reciprocal of the number of quanta required to elicit a constant electroretinogram of 350 V.N. mediator is maximally sensitive at 480 nm, although it is very sensitive over a broad range from 400 nm to 540 nm (Fig. 4). Selective adaptation experiments (Fig. 5) and changes in the time characteristics of the electroretinogram under conditions of dark and green adaptation (Fig. 2) indicate the presence of a multi-receptor system.We thank Dr. Olga Hartman and Dr. Kristian Fauchald for their help with the natural history and identification of specimens. We also thank Josephine Yingst for her help in collection of specimens. This research was supported by a USC Biomedical Grant 5730 and by AFOSR Contract F 44620-70-C-0113.     

Living foraminifera and total populations in salt marsh peat cores: Kelsey Marsh (Clinton, CT) and the Great Marshes (Barnstable, MA)

Common species of intertidal agglutinated benthic foraminifera in salt marshes in Massachusetts and Connecticut live predominantly at the marsh surface and in the topmost sediment (0–2.5 cm), but a considerable part of the fauna lives at depths of 2.5–15 cm. Few specimens are alive at depths of 15–25 cm, with rare individuals alive between 25–50 cm in the sediments. Specimens living between the sediment surface and 25 cm deep occur in all marsh settings, whereas specimens living deeper than 25 cm are restricted to cores from the lower and middle marsh, and have an irregular distribution-with-depth. Lower and middle marsh areas are bioturbated by metazoa, suggesting that living specimens reach these depths at least in part by bioturbation. High-marsh sediments in New England consist of very dense mats of Spartina patents or Distichlis spicata roots and are not bioturbated by metazoa. In this marsh region bioturbation by plant roots and vertical fluid motion may play a role in moving the foraminifera into the sediment. The depth-distribution of living specimens varies with species: living specimens of Trochammina inflata consistently occur at the deepest levels. This suggests that species have differential rates of survival in the sediment, possibly because of differential adaptation to severe dysoxia to anoxia, or because of differing food preferences. There is no simple correlation between depth-in-core and faunal diversity, absolute abundance, and species composition of the assemblages. It is therefore possible to derive a signal of faunal changes and thus the environmental changes that may have caused them from the complex faunal signal of fossil assemblages.     

Morphofunctional changes of the interrenal gland and of ultrastructure of chloride cells in intact and hypophysectomized juveniles of starred sturgeon <Emphasis Type="Italic">Acipenser stellatus</Emphasis> (Acipenseridae) in the course of adaptation to sea water

The impact of hypophysectomy on the state of the interrenal gland and ultrastructure of chloride cells of gills is investigated in 18-month old juveniles of starred sturgeon Acipenser stellatus in the process of its adaptation to artificial sea water (14.6‰). Hypophysectomized juveniles, similarly to intact juveniles, are able to support a relative stability of osmolarity of blood serum in the course of adaptation to sea water by transition from hyperosmotic to hypoosmotic type of osmoregulation. Changes in the investigated parameters of cells of the interrenal gland (volume of nuclei, areas of cells and of lipophilic vacuoles) occurring in the hypophysectomized and in intact specimens in the process of adaptation to sea water are generally similar, but have different dynamics. In contrast to many teleostean species, in acipenserids the hypophyectomy does not cause atrophy of the interrenal gland. The latter is incorporated in the process of regulation in the course of adaptation of fish to sea water. Hypophyecotmy results in partial destruction of organoids in some chloride cells of gills. However, when the fish are transferred to sea water, the structural changes occur in chloride cells characteristic of their transition to the excretory state. This may happen only at activation of the transport enzyme Na⁺/K⁺-ATPase of these cells by cortisol produced by the interrenal gland. In the absence of hypophysis, the functional connection of organs of the axis hypothalamus (ACTH-immunopositive cells of tuberal nucleus) → the interrenal gland → chloride cells is realized in the fish.     

The parameters of reproduction, sizes, and activities of hydrolases in Daphnia magna straus of successive generations affected by Roundup herbicide

The influence of sublethal concentrations of Roundup (25 and 50 mg/l of the active compound glyphosate) was studied in the Daphnia magna Straus of successive generations. The toxic effects were assessed by the parameters of fecundity, quality of progeny, and linear sizes of daphnia, as well as by the activities of carbohydrases and proteases. The effect of the toxicant may be traced both in the parent specimens and in the specimens of successive generations. No adaptation to Roundup’s toxic impact was revealed for four generations of Daphnia magna. However, a considerable decrease in resistance to the herbicide was noted in the fourth generation when compared to the maternal line.     

Photosensory Adaptation in Plants

Photosensory adaptation (range adjustment) is of great importance in plants (including fungi and various microorganisms) that operate in large intensity ranges. The adaptation mechanisms of plants have some features in common with those of vertebrates and invertebrates. As with those systems, plants have biphasic exponential dark-adaptation kinetics, that are much slower than the corresponding light adaptation kinetics. One needs to distinguish between sensor adaptation, which regulates range adjustment, and effector adaptation (habituation), which regulates the motor apparatus of the organism (flagellar movement or cell wall growth). In Phycomyces, and perhaps Stentor, sensor adaptation is mediated by the photoreceptor system. In contrast to vertebrates and invertebrates, dark adaptation can be controlled in some plants by special photoreceptors. In Phycomyces, these can be either photo-products of the actinic photoreceptor(s) or not yet identified receptor pigments. In higher plants phytochrome can alter the state of adaptation.     

Guloptiloides: an Extraordinary New Carnivorous Genus of Baetidae (Ephemeroptera)

Guloptiloides (Ephemeroptera, Baetidae), gen.n., is described to accomodate the species G. gargantua (larvae) and G. spA (female imagoes) based on specimens from the Eastern coast of Madagascar. Larvae of Guloptiloides are remarkable by the adaptation of the mouthparts to a predatory diet. It is also distinct from other genera in that adults have hindwings with 3 well-marked longitudinal veins and a single extremely developed spur on the costal margin. Affinities and ecology are discussed.     

Electrophysiological responses to light in the compound eyes of some stored-product insects

That stored-product insects demonstrate behavioral response to light is well-known (Stermer, 1959; Sohi, 1966; Yinon & Shulov, 1966). The question asked is whether these insects, which exist always in conditions of low illumination or darkness, possess a normal visual mechanism. In order to clarify this, electroretinograms have been recorded from the compound eyes of the adults of the yellow mealworm beetle Tenebrio molitor L., the hide beetle Dermestes maculatus De G., and the khapra beetle Trogoderma granarium Everts. Nineteen specimens were the subject of experiments in T. molitor and four in each of the other species. Conventional optical and electronic equipment were used to stimulate the eyes and to record the response (Yinon & Aucrbach, 1969). A computer of average transients was used and permitted accurate diagnosis of the response pattern. Fifty responses for each stimulus type (i.e., light intensity) were averaged. A dark adaptation of 5–10 minutes was given before each experiment.     

Interactions among the three adaptation systems of Bacillus subtilis chemotaxis as revealed by an in vitro receptor‐kinase assay

The Bacillus subtilis chemotaxis pathway employs three systems for sensory adaptation: the methylation system, the CheC/CheD/CheYp system, and the CheV system. Little is known in general about how these three adaptation systems contribute to chemotaxis in B. subtilis and whether they interact with one another. To further understand these three adaptation systems, we employed a quantitative in vitro receptor‐kinase assay. Using this assay, we were able to determine how CheD and CheV affect receptor‐kinase activity as a function of the receptor modification state. CheD was found to increase receptor‐kinase activity, where the magnitude of the increase depends on the modification state of the receptor. The principal new findings concern CheV. Little was known about this protein before now. Our data suggest that this protein has two roles depending on the modification state of the receptor, one for sensory adaptation when the receptors are modified (methylated) and the other for signal amplification when they are unmodified (unmethylated). In addition, our data suggest that methylation of site 630 tunes the strength of the CheV adaptation system. Collectively, our results provide new insight regarding the integrated function of the three adaptation systems in B. subtilis.     

In vitro tetracycline susceptibility of Chlamydia trachomatis in clinical specimens

A novel approach to determine the tetracycline susceptibility of Chlamydia trachomatis directly from specimens without cell culture propagation and adaptation has been explored. Out of a total of 1290 genital specimens from a sexually transmitted disease clinic, 211 (16.4%) were positive for C. trachomatis. A tetracycline concentration of 0.032 g/ml completely inhibited the appearance of inclusions in all of the 211 positive specimens. Of the positive specimens, 120 (56.9%) and 18 (8.5%) respectively showed the presence of 1 to 9 and 100 or more inclusions per microtiter well in antibiotic free medium. Other antibiotics are being tested in the same manner.A part of this paper was presented at the Canadian Public Health Association, STD meeting in Ottawa, Canada, 28–29 October 1985     

New proconsuloid postcranials from the early Miocene of Kenya

New early Miocene forelimb fossils have been recovered from the Songhor and Lower Kapurtay localities in southwestern Kenya. We describe four specimens that are similar in size and functional capabilities. Their specific allocation is problematic but these forelimb specimens must belong to either Rangwapithecus gordoni or Proconsul africanus. If these new postcranial specimens should belong to R. gordoni, on the basis of size and common dental specimens found at Songhor, they represent a new elbow complex. The morphology of these fossils is anatomically and functionally similar to that of Proconsul. The proconsuloid elbow complex allows extensive forelimb rotations and is capable of performing arboreal quadrupedalism and climbing activities. No suspensory adaptations are apparent. The proconsuloid elbow complex remains a good ancestral condition for hominoid primates.     

Rapid genetic adaptation precedes the spread of an exotic plant species

Human activities have increasingly introduced plant species far outside their native ranges under environmental conditions that can strongly differ from those originally met. Therefore, before spreading, and potentially causing ecological and economical damage, non‐native species may rapidly evolve. Evidence of genetically based adaptation during the process of becoming invasive is very scant, however, which is due to the lack of knowledge regarding the historical genetic makeup of the introduced populations and the lack of genomic resources. Capitalizing on the availability of old non‐native herbarium specimens, we examined frequency shifts in genic SNPs of the Pyrenean Rocket (Sisymbrium austriacum subsp. chrysanthum), comparing the (i) native, (ii) currently spreading non‐native and (iii) historically introduced gene pool. Results show strong divergence in flowering time genes during the establishment phase, indicating that rapid genetic adaptation preceded the spread of this species and possibly assisted in overcoming environmental constraints.     

New early Eocene anaptomorphine primate (Omomyidae) from the Washakie Basin,Wyoming, with comments on the phylogeny and paleobiology of anaptomorphines

Recent paleontological collecting in the Washakie Basin, southcentral Wyoming, has resulted in the recovery of over 100 specimens of omomyid primates from the lower Eocene Wasatch Formation. Much of what is known about anaptomorphine omomyids is based upon work in the Bighorn and Wind River Basins of Wyoming. This new sample documents greater taxonomic diversity of omomyids during the early Eocene and contributes to our understanding of the phylogeny and adaptations of some of these earliest North American primates. A new middle Wasatchian (Lysitean) anaptomorphine, Anemorhysis savagei, n. sp., is structurally intermediate between Teilhardina americana and other species of Anemorhysis and may be a sister group of other Anemorhysis and Trogolemur. Body size estimates for Anemorhysis, Tetonoides, Trogolemur, and Teilhardina americana indicate that these animals were extremely small, probably less than 50 grams. Analysis of relative shearing potential of lower molars of these taxa indicates that some were primarily insectivorous, some primarily frugivorous, and some may have been more mixed feeders. Anaptomorphines did not develop the extremes of molar specialization for frugivory or insectivory seen in extant prosimians. Incisor enlargement does not appear to be associated with specialization in either fruits or insects but may have been an adaptation for specialized grooming or food manipulation. © 1994 Wiley-Liss, Inc.