Why did heterospory evolve?

The primitive land plant life cycle featured the production of spores of unimodal size, a condition called homospory. The evolution of bimodal size distributions with small male spores and large female spores, known as heterospory, was an innovation that occurred repeatedly in the history of land plants. The importance of desiccation‐resistant spores for colonization of the land is well known, but the adaptive value of heterospory has never been well established. It was an addition to a sexual life cycle that already involved male and female gametes. Its role as a precursor to the evolution of seeds has received much attention, but this is an evolutionary consequence of heterospory that cannot explain the transition from homospory to heterospory (and the lack of evolutionary reversal from heterospory to homospory). Enforced outcrossing of gametophytes has often been mentioned in connection to heterospory, but we review the shortcomings of this argument as an explanation of the selective advantage of heterospory. Few alternative arguments concerning the selective forces favouring heterospory have been proposed, a paucity of attention that is surprising given the importance of this innovation in land plant evolution. In this review we highlight two ideas that may lead us to a better understanding of why heterospory evolved. First, models of optimal resource allocation – an approach that has been used for decades in evolutionary ecology to help understand parental investment and other life‐history patterns – suggest that an evolutionary increase in spore size could reach a threshold at which small spores yielding small, sperm‐producing gametophytes would return greater fitness per unit of resource investment than would large spores and bisexual gametophytes. With the advent of such microspores, megaspores would evolve under frequency‐dependent selection. This argument can account for the appearance of heterospory in the Devonian, when increasingly tall and complex vegetative communities presented competitive conditions that made large spore size advantageous. Second, heterospory is analogous in many ways to anisogamy. Indeed, heterospory is a kind of re‐invention of anisogamy within the context of a sporophyte‐dominant land plant life cycle. The evolution of anisogamy has been the subject of important theoretical and empirical investigation. Recent work in this area suggests that mate‐encounter dynamics set up selective forces that can drive the evolution of anisogamy. We suggest that similar dispersal and mating dynamics could have underlain spore size differentiation. The two approaches offer predictions that are consistent with currently available data but could be tested far more thoroughly. We hope to re‐establish attention on this neglected aspect of plant evolutionary biology and suggest some paths for empirical investigation.     

Circum-Antarctic continental distribution patterns in pteridophyte species

Four major austral continental distribution patterns are evident in pteridophytes. Twenty-two species are completely circum-Antarctic. Another 39 species are partially circum-Antarctic, occurring in Australasia (Australia and New Zealand) and Africa (including Madagascar) but not South America, while 29 are in Africa and South America but not Australasia, and 13 are in South America and Australasia but not Africa. Two hypotheses are considered as explanations for the patterns: continental drift following the breakup of Gondwana and long-distance dispersal. Fossil evidence indicates that the majority of pteridophyte families involved appeared after the southern continents had drifted apart, so long-distance dispersal is likely to explain the distribution of species in these families on now widely separated continents. For those families extant before the break-up, there is no indication in the fossil record that the species involved were present in Gondwana. Aspects of the ecology of the species that are partly or completely circum-Antarctic indicate that long-distance dispersal, rather than continental drift, is a likely explanation for the patterns.     

Differential sensitivities to gamma radiation of human bladder and testicular tumour cell lines

Gamma radiation sensitivities of continuous cell lines from nine human tumours were measured, comparing four derived from transitional cell carcinomas of the bladder with five from non-seminomatous germ cell tumours of the testis. The testicular cells were significantly more radiosensitive than the bladder cells, corresponding to the response to therapy of these tumour types in patients. These observations indicate that radiosensitivity is retained in vitro and is an inherent property of the testicular tumour cells. These gamma radiation sensitivities were compared with those of SV40-transformed fibroblasts derived from a normal individual and one with the heritable disease, ataxia-telangiectasia (A-T). The bladder cells had gamma radiation sensitivities similar to that of the SV40-transformed normal line. The testicular cells were hypersensitive to gamma radiation, although not as sensitive as the SV40-transformed A-T line. A-T cells, unlike those derived from normal individuals, continue to synthesize DNA at a normal rate following radiation exposure, prompting a comparison of the kinetics of DNA synthesis in three bladder and three testicular tumour cell lines. One of the bladder and two testicular lines showed a reduced inhibition when compared to the other tumour cell lines and the SV40-transformed normal line. Thus there was no clear association between DNA synthesis inhibition and radiosensitivity.     

Influence of pH on organic acid production by Clostridium sporogenes in test tube and fermentor cultures.

The influence of pH on the growth parameters of and the organic acids produced by Clostridium sporogenes 3121 cultured in test tubes and fermentors at 35 degrees C was examined. Specific growth rates in the fermentor maintained at a constant pH ranged from 0.20 h-1 at pH 5.00 to 0.86 h-1 at pH 6.50. Acetic acid was the primary organic acid in supernatants of 24-h cultures; total organic acid levels were 2.0 to 22.0 mumol/ml. Supernatants from pH 5.00 and 5.50 cultures had total organic acid levels less than one-third of those found at pH 6.00 to 7.00. The specific growth rates of the test tube cultures ranged from 0.51 h-1 at pH 5.00 to 0.95 h-1 at pH 6.50. The pH of the medium did not affect the average total organic acid content (51.5 mumol/ml) but did affect the distribution of the organic acids, which included formic, acetic, propionic, butyric, 3-(p-hydroxyphenyl)propionic, and 3-phenylpropionic acids. Butyric acid levels were lower, but formic and propionic acid levels were higher, at pH 5.00 than at other pHs.     

Interaction of substrates and substrate-like inhibitors with the peptidyltransferase center from Escherichia coli ribosomes

The binding isotherms of CACCA(3'NHPhe----Ac) and CACCA(3'NHPhe) to E. coli ribosomes and 50S subunits were measured. A theoretical model of adsorption for the case of cooperative interaction between two ligands adsorbed on a ribosome was designated. The analysis of the experimental binding isoterms leads to the following conclusions. A ribosome (or subunit) binds one CACCA (3'NHPhe----Ac) molecule to donor site of the peptidyl transferase center, but two CACCA (3'NHPhe) molecules to both donor and acceptor sites. The binding of CACCA (3'NHPhe) to ribosomes (or subunits) is a cooperative process, characterized by the cooperativity coefficient tau = 40 +/- 5 or more. When model substrates CACCA-Phe, CACCA-Leu and CACCA-Val were taken instead of CACCA (3'NHPhe) in the incubation mixture with ribosomes, dipeptides were obtained even in the case, when ratio [model substrate]: [ribosome] (in moles) was much lower than 1. Puromycin binding to acceptor site with constant (1-2) X 10(4) M-1 also stimulates CACCA(3'NHPhe----Ac) adsorption to the donor site of ribosomes with cooperativity coefficient being equal to 1.5-2.5. It is also shown that cytidine 5'-phosphate binding to the donor site increases kappa cat of the reaction of minimal donors with CACCA-Phe by 1.5 orders of magnitude but has no effect on Km of this reaction. These facts point out that cytidine 5'-phosphate being adsorbed on the corresponding area of the donor site leads to the conversion of low-productive complex [ribosome + minimal donor substrate + acceptor substrate] into high-productive complex [ribosome + minimal donor substrate + acceptor substrate + cytidine 5'-phosphate].     

Localization of the herpes simplex virus type 1 65-kilodalton DNA-binding protein and DNA polymerase in the presence and absence of viral DNA synthesis.

Using indirect immunofluorescence, well-characterized monoclonal and polyclonal antibodies, and temperature-sensitive (ts) mutants of herpes simplex virus type 1, we demonstrated that the 65-kilodalton DNA-binding protein (65KDBP), the major DNA-binding protein (infected cell polypeptide 8 [ICP8]), and the viral DNA polymerase (Pol) colocalize to replication compartments in the nuclei of infected cells under conditions which permit viral DNA synthesis. When viral DNA synthesis was blocked by incubation of the wild-type virus with phosphonoacetic acid, the 65KDBP, Pol, and ICP8 failed to localize to replication compartments. Instead, ICP8 accumulated nearly exclusively to prereplication sites, while the 65KDBP was only diffusely localized within the nuclei. Although some of the Pol accumulated in prereplication sites occupied by ICP8 in the presence of phosphonoacetic acid, a significant amount of Pol also was distributed throughout the nuclei. Examination by double-labeling immunofluorescence of DNA- ts mutant virus-infected cells revealed that the 65KDBP also did not colocalize with ICP8 to prereplication sites at temperatures nonpermissive for virus replication. These results are in disagreement with the hypothesis that ICP8 is the major organizational protein responsible for attracting other replication protein to prereplication sites in preparation for viral DNA synthesis (A. de Bruyn Kops and D. M. Knipe, Cell 55:857-868, 1988), and they suggest that other viral proteins, perhaps in addition to ICP8, or replication fork progression per se are required to organize the 65KDBP.