Two mouse early embryonic beta-globin gene sequences. Evolution of the nonadult beta-globins.

We have determined the complete nucleotide sequence of two early embryonic beta-globin genes of the BALB/c mouse: beta h0 and beta h1 X beta h1 codes for the embryonic z protein, while the beta h0 gene may be a minor early embryonic beta-globin gene. The general sequence organization of both genes is entirely analogous to other functional globin genes. There is, however, a 220-base pair insertion of unique sequence within the first intron of beta h0 X beta h0 and beta h1 are 96% homologous for 260 base pairs 5' to the AUG initiation codon, and 93% homologous throughout their coding regions. Analysis of the 5'-flanking sequence demonstrates that these genes are more nonadult-like than adult-like. The sequences show evidence for gene conversions among the mouse nonadult beta-globin genes that were limited to individual exons, presumably by the presence of non-homologous introns. We propose that this arrangement has the beneficial evolutionary effect of allowing gene conversion to act independently on regions of the protein with different structural or functional responsibilities. beta h0 and beta h1 are evolutionary homologs to the human fetal and rabbit beta 3 genes, while their manner of expression is similar to rabbit beta 3 and dissimilar to human fetal expression. The evolutionary history of the human beta-globin genes, therefore, includes the recruitment of an embryonic gene to fetal developmental control

Importance of quantitative genetic variations in the etiology of hypertension

Importance of quantitative genetic variations in the etiology of hypertension. Recent progress has been remarkable in identifying mutations which cause diseases (mostly uncommon) that are inherited simply. Unfortunately, the common diseases of humankind with a strong genetic component, such as those affecting cardiovascular function, have proved less tractable. Their etiology is complex with substantial environmental components and strong indications that multiple genes are implicated. In this article, we consider the genetic etiology of essential hypertension. After presenting the distribution of blood pressures in the population, we propose the hypothesis that essential hypertension is the consequence of different combinations of genetic variations that are individually of little consequence. The candidate gene approach to finding relevant genes is exemplified by studies that identified potentially causative variations associated with quantitative differences in the expression of the angiotensinogen gene (AGT). Experiments to test causation directly are possible in mice, and we describe their use to establish that blood pressures are indeed altered by genetic changes in AGT expression. Tests of differences in expression of the genes coding for the angiotensin-converting enzyme (ACE) and for the natriuretic peptide receptor A are also considered, and we provide a tabulation of all comparable experiments in mice. Computer simulations are presented that resolve the paradoxical finding that while ACE inhibitors are effective, genetic variations in the expression of the ACE gene do not affect blood pressure. We emphasize the usefulness of studying animals heterozygous for an inactivating mutation and a wild-type allele, and briefly discuss a way of establishing causative links between complex phenotypes and single nucleotide polymorphisms

The F-type 5′ motif of mouse L1 elements: a major class of L1 termini similar to the A-type in organization but unrelated in sequence

It has previously been shown that the L1 family in the mouse (L1Md) contains two alternative 5' ends called the A- and F-type sequences (1,2). We show here that the F-type element is a major class of murine L1 elements and report on the details of organization of the 5' motif of these F-type elements. Although the A- and F-type 5' sequences share no detectable sequence homology the organization of an F-type 5' end is strikingly similar to that of an A-type. That is, the F-type 5' sequences consist of a tandem array of a small number of 206 bp monomers while the A-type 5' motif consists of a tandem array of 208 bp monomers. All of the A-type elements characterized to date have a truncated monomer at the 5' end of the array. Many of the F-type elements are also terminated at the 5' end by a truncated copy but unlike the A-type elements some F-type elements terminate with a monomer which is within a few nucleotides of being complete. In addition the F-type consensus sequence, in contrast to the A-type sequence, shows homology (70%) to the body of the L1Md starting at the position where the monomer joins the rest of the L1 element

Homelessness and the meaning of home: rooflessness or rootlessness?

This paper has several objectives. These are: (1) to analyse the meaning of homelessness in the light of recent contributions on the meaning of home: (2) to criticize some current perspectives on homelessness as a social problem; (3) to identify and explore a number of different dimensions of the meaning of home and homelessness; (4) to reassess the evidence on the context of home and homelessness, and re-examine the meaning of homelessness in the light of that reassessed evidence; and (5) to explain the political meaning of homelessness as expressed in official definitions, legislation and state provision (or lack of it)

The diagonal-traverse homology search algorithm for locating similarities between two sequences

We present a fast computer algorithm for finding homology between two DNA sequences. It generates a two-dimensional display in which a diagonal string of dots represents a stretch of homology between the two sequences. Our algorithm performs the search very rapidly, and has no internal data storage requirement except for the sequences themselves. These characteristics make it particularly well suited for execution on microcomputers. Without slowing execution, the matching criterion can be that a specified fraction of contiguous bases must be identical. Even with gapped sequences, we have found large search windows to be surprisingly good for detecting poor homologies with nearly complete background suppression. A diagonal search pattern is used that reports the finds in a compact and logically ordered form. A simple and rapid plotting algorithm for unsophisticated printers is also reported

Locations of three repetitive sequence families found in BALB/c adult β-globin clones

Three different repeat sequences have been mapped within the cloned EcoRI fragments that Contain the adult β-globin genes from the BALB/c (Hd

Dynamic Coupling and Allosteric Behavior in a Nonallosteric Protein †

Long-range intraprotein interactions give rise to many important protein behaviors. Understanding how energy is transduced through protein structures to either transmit a signal or elicit conformational changes is therefore a current challenge in structural biology. In an effort to understand such linkages, multiple V→A mutations were made in the small globular protein eglin c. The physical responses, as mapped by NMR spin relaxation, residual dipolar couplings (RDCs), and scalar couplings, illustrate that the interior of this non-allosteric protein forms a dynamic network and that local perturbations are transmitted as dynamic and structural changes to distal sites as far as 16 Å away. Two basic types of propagation responses were observed: contiguous pathways of enhanced (attenuated) dynamics with no change in structure; and dispersed (non-contiguous) changes in methyl rotation rates that appear to result from subtle deformation of backbone structure. In addition, energy transmission is found to be unidirectional. In one mutant, an allosteric conformational change of a side chain is seen in the context of a pathway of propagated changes in ps-ns dynamics. The observation of so many long-range interactions in a small, rigid system lends experimental weight to the idea that all well-folded proteins inherently possess allosteric features [Gunasekaran et al. (2004) Proteins 57, 433−443], and that dynamics are a rich source of information for mapping and gaining mechanistic insight into communication pathways in individual proteins

The L1Md long interspersed repeat family in the mouse: almost all examples are truncated at one end

Caractérisation d'un grand élément répétitif détecté en sept localisations différentes dans le locus globine β de la souris Balb/C. Cette répétition possède la même extrémité de l'élément conservé alors que l'autre extrémité se termine en un point différent chez chaque membre de cette famille de répétitions

Mutational analysis of human immunodeficiency virus type 1 protease suggests functional homology with aspartic proteinases.

Processing of the retroviral gag and pol gene products is mediated by a viral protease. Bacterial expression systems have been developed which permit genetic analysis of the human immunodeficiency virus type 1 protease as measured by cleavage of the pol protein precursor. Deletion analysis of the pol reading frame locates the sequences required to encode a protein with appropriate proteolytic activity near the left end of the pol reading frame but largely outside the gag-pol overlap region, which is at the extreme left end of pol. Most missense mutations within an 11-amino-acid domain highly conserved among retroviral proteases and with sequence similarity to the active site of aspartic proteinases abolish appropriate processing, suggesting that the retrovirus proteases share a catalytic mechanism with aspartic proteinases. Substitution of the amino acids flanking the scissile bond at three of the processing sites encoded by pol demonstrates distinct sequence requirements for cleavage at these different sites. The inclusion of a charged amino acid at the processing site blocks cleavage. A subset of these substitutions also inhibits processing at the nonmutated sites

Detection of Native-State Nonadditivity in Double Mutant Cycles via Hydrogen Exchange

Proteins have evolved to exploit long-range structural and dynamic effects as a means of regulating function. Understanding communication between sites in proteins is therefore vital to our comprehension of such phenomena as allostery, catalysis, and ligand binding/ejection. Double mutant cycle analysis has long been used to determine the existence of communication between pairs of sites—proximal or distal—in proteins. Typically, non-additivity (or “thermodynamic coupling”) is measured from global transitions in concert with a single probe. Here, we have applied the atomic resolution of NMR in tandem with native-state hydrogen exchange (HX) to probe the structure/energy landscape for information transduction between a large number of distal sites in a protein. Considering the event of amide proton exchange as an energetically quantifiable structural perturbation, m n-dimensional cycles can be constructed from mutation of n-1 residues, where m is the number of residues for which HX data is available. Thus, efficient mapping of a large number of couplings is made possible. We have applied this technique to one additive and two non-additive double mutant cycles in a model system, eglin c. We find heterogeneity of HX-monitored couplings for each cycle, yet, averaging results in strong agreement with traditionally measured values. Furthermore, long-range couplings observed at locally exchanging residues indicate that the basis for communication can occur within the native state ensemble, a conclusion which is not apparent from traditional measurements. We propose that higher-order couplings can be obtained and show that such couplings provide a mechanistic basis for understanding lower-order couplings, via “spheres of perturbation”. The method is presented as an additional tool for identifying a large number of couplings with greater coverage of the protein of interest