Fitness Assays Reveal Incomplete Functional Redundancy of the HoxA1 and HoxB1 Paralogs of Mice

Gene targeting techniques have led to the phenotypic characterization of numerous genes; however, many genes show minimal to no phenotypic consequences when disrupted, despite many having highly conserved sequences. The standard explanation for these findings is functional redundancy. A competing hypothesis is that these genes have important ecological functions in natural environments that are not needed under laboratory settings. Here we discriminate between these hypotheses by competing mice (Mus musculus) whose Hoxb1 gene has been replaced by Hoxa1, its highly conserved paralog, against matched wild-type controls in seminatural enclosures. This Hoxb1^A1 swap was reported as a genetic manipulation resulting in no discernible embryonic or physiological phenotype under standard laboratory tests. We observed a transient decline in first litter size for Hoxb1^A1 homozygous mice in breeding cages, but their fitness was consistently and more dramatically reduced when competing against controls within seminatural populations. Specifically, males homozygous for the Hoxb1^A1 swap acquired 10.6% fewer territories and the frequency of the Hoxb1^A1 allele decreased from 0.500 in population founders to 0.419 in their offspring. The decrease in Hoxb1^A1 frequency corresponded with a deficiency of both Hoxb1^A1 homozygous and heterozygous offspring. These data suggest that Hoxb1 and Hoxa1 are more phenotypically divergent than previously reported and support that sub- and/or neofunctionalization has occurred in these paralogous genes leading to a divergence of gene function and incomplete redundancy. Furthermore, this study highlights the importance of obtaining fitness measures of mutants in ecologically relevant conditions to better understand gene function and evolution.     

A genetic test for recruitment enhancement in Chesapeake Bay oysters, Crassostrea virginica, after population supplementation with a disease tolerant strain

Many of the methods currently employed to restore Chesapeake Bay populations of the eastern oyster, Crassostrea virginica, assume closed recruitment in certain sub-estuaries despite planktonic larval durations of 2–3 weeks. In addition, to combat parasitic disease, artificially selected disease tolerant oyster strains are being used for population supplementation. It has been impossible to fully evaluate these unconventional tactics because offspring from wild and selected broodstock are phenotypically indistinguishable. This study provides the first direct measurement of oyster recruitment enhancement by using genetic assignment tests to discriminate locally produced progeny of a selected oyster strain from progeny of wild parents. Artificially selected oysters (DEBY strain) were planted on a single reef in each of two Chesapeake Bay tributaries in 2002, but only in the Great Wicomico River (GWR) were they large enough to potentially reproduce the same year. Assignment tests based on eight microsatellite loci and mitochondrial DNA markers were applied to 1579 juvenile oysters collected throughout the GWR during the summer of 2002. Only one juvenile oyster was positively identified as an offspring of the 0.75 million DEBY oysters that were planted in the GWR, but 153 individuals (9.7%) had DEBY ×wild F1 multilocus genotypes. Because oyster recruitment was high across the region in 2002, the proportionately low enhancement measured in the GWR would not otherwise have been recognized. Possible causes for low enhancement success are discussed, each bearing on untested assumptions underlying the restoration methods, and all arguing for more intensive evaluation of each component of the restoration strategy.     

Catalytic mechanism of the dihydrofolate reductase reaction as determined by pH studies

The variation with pH of the kinetic parameters of the reaction catalyzed by dihydrofolate reductase from Escherichia coli has been determined with the aim of elucidating the chemical mechanism of the reaction. The (V/K)DHF and V profiles indicated that protonation enhances the observed rate of interaction of dihydrofolate (DHF) with the enzyme-NADPH complex as well as the maximum velocity of the reaction. The pKa value of 8.09 observed in the (V/K)DHF profile is similar to that of 7.9 observed in the Ki profile for 2,4-diamino-6,7-dimethylpteridine while the pKa value of the V profile is displaced to 8.4. From the magnitude of the pH-independent value for (V/K)DHF, it is concluded that unprotonated dihydrofolate must react, at neutral pH, with the protonated form of the enzyme. The D(V/K)DHF value is independent of pH and equal to unity whereas the DV value varies as a wave function of pH with limiting values of 1.5 and 1.0 at low and high pH, respectively. It is proposed that dihydrofolate reacts with the unprotonated enzyme-NADPH complex to form a dead-end complex and with the protonated form of the same complex to form a productive complex. Further, it is considered that the protonated carboxyl of Asp-27 at the active site of the enzyme is responsible for the protonation of the N-5 nitrogen of dihydrofolate and that this protonation precedes and facilitates hydride transfer.     

The Effects of Two Polymorphisms on p21cip1 Function and Their Association with Alzheimer’s Disease in a Population of European Descent

With the exception of ApoE4, genome-wide association studies have failed to identify strong genetic risk factors for late-onset Alzheimer’s disease, despite strong evidence of heritability, suggesting that many low penetrance genes may be involved. Additionally, the nature of the identified genetic risk factors and their relation to disease pathology is also largely obscure. Previous studies have found that a cancer-associated variant of the cell cycle inhibitor gene p21^cip1 is associated with increased risk of Alzheimer’s disease. The aim of this study was to confirm this association and to elucidate the effects of the variant on protein function and Alzheimer-type pathology. We examined the association of the p21^cip1 variant with Alzheimer’s disease and Parkinson’s disease with dementia. The genotyping studies were performed on 719 participants of the Oxford Project to Investigate Memory and Ageing, 225 participants of a Parkinson’s disease DNA bank, and 477 participants of the Human Random Control collection available from the European Collection of Cell Cultures. The post mortem studies were carried out on 190 participants. In the in-vitro study, human embryonic kidney cells were transfected with either the common or rare p21^cip1 variant; and cytometry was used to assess cell cycle kinetics, p21^cip1 protein expression and sub-cellular localisation. The variant was associated with an increased risk of Alzheimer’s disease, and Parkinson’s disease with dementia, relative to age matched controls. Furthermore, the variant was associated with an earlier age of onset of Alzheimer’s disease, and a more severe phenotype, with a primary influence on the accumulation of tangle pathology. In the in-vitro study, we found that the SNPs reduced the cell cycle inhibitory and anti-apoptotic activity of p21^cip1. The results suggest that the cancer-associated variant of p21^cip1 may contribute to the loss of cell cycle control in neurons that may lead to Alzheimer-type neurodegeneration.     

A Porcine Epidemic Diarrhea Virus Outbreak in One Geographic Region of the United States: Descriptive Epidemiology and Investigation of the Possibility of Airborne Virus Spread

This study describes a spring 2013 outbreak of porcine epidemic diarrhea virus (PEDv), using data from 222 swine sites in 14 counties area in 4 contiguous states in the United States. During the outbreak, the premises-level incidence of PEDv was 40.5 percent (90/222 sites). One of the three companies from which data were collected had a lower incidence (19.5 percent) than the other two companies (41.1 and 47.2 percent). Sow sites had the highest incidence of PEDv during the outbreak (80.0 percent). Spatial analysis showed that PEDv was clustered rather than randomly distributed, which suggested that sites near a positive site had increased risk of acquiring PEDv infection. Meteorological data were used to investigate the hypothesis that PEDv was spread by air. If airborne dissemination played a role in this outbreak, we would expect the direction of disease spread to correlate with the predominant wind direction. Two methods were used to determine the direction of disease spread—linear direction mean analysis in ArcGIS and the direction test in ClusterSeer. The former method indicated PEDv spread was south to slightly southwest, and the latter indicated spread was to the southeast. The predominant wind direction during the month of the outbreak was toward the south, with some southeast and southwest winds; the strongest wind gusts were toward the southwest. These findings support the hypothesis that PEDv was spread by air. The results, however, should be interpreted cautiously because we did not have information on direct and indirect contacts between sites, such as movement of trucks, feed, pigs or people. These types of contacts should be evaluated before pathogen spread is attributed to airborne mechanisms. Although this study did not provide a definitive assessment of airborne spread of PEDv, we believe the findings justify additional research to investigate this potential mechanism of transmission.     

Community Composition and Density of Methanogens in the Foregut of the Tammar Wallaby (Macropus eugenii)

The composition of the methanogenic archaeal community in the foregut contents of Tammar wallabies (Macropus eugenii) was studied using 16S rRNA and methyl coenzyme reductase subunit A (mcrA) gene clone libraries. Methanogens belonging to the Methanobacteriales and a well-supported cluster of uncultivated archaeon sequences previously observed in the ovine and bovine rumens were found. Methanogen densities ranged from 7.0 × 10⁵ and 3.9 × 10⁶ cells per gram of wet weight.Kangaroos and wallabies belong to the marsupial family Macropodidae and are native to Australia. Because of their geographical isolation, macropod marsupials have evolved separately from other herbivorous animals, such as ruminants, but like ruminants, macropods have a complex gut microbiome that includes fungi, archaea, bacteria, and protozoa to coordinate plant biomass breakdown (11). The macropod foregut is functionally analogous to the rumen, yet for reasons unknown, macropod species produce relatively low levels of methane compared to ruminants (5, 13, 30).New species of bacteria (21) and protozoa (2-4) have been indentified in the macropod foregut, and the presence of fungi has also been reported (5). Preliminary studies have shown that methanogens are present in the kangaroo foregut (1) but can be absent or at levels below detection limits (22). This study represents the first attempt to describe the diversity of methanogens residing in the macropod foregut by using 16S rRNA and methyl coenzyme reductase A (mcrA) clone libraries in combination with quantitative real-time PCR.     

Relationships among the polypeptides of Newcastle disease virus.

We have studied the relationships among the polypeptides of Newcastle disease virus by using both kinetic and tryptic peptide analyses. The results of our tryptic peptide analyses suggest that there are at least six unique viral polypeptides--L, HN, FO(F), NP, M, and a 47,000-dalton polypeptide. The small virion glycopolypeptide F is related to FO, a glycopolypeptide found only in infected cells. In addition, several smaller polypeptides, including a 53,000-dalton polypeptide found both in purified virions and in infected cells, are related to the nucleocaspid protein. Kinetic analysis of each viral polypeptide reveals that all of the major viral polypeptides, with the possible exception of L, are stable after an amino acid chase. A precursor-product relationship between FO and F was not demonstrable by pulse-chase experiments. Also, almost the same relative amount of F, the putative product, was present in infected cultures after either 5 or 30 min of radioisotopic labeling. These results suggest that FO is processed rapidly.