The cytoskeleton adaptor protein ankyrin-1 is upregulated by p53 following DNA damage and alters cell migration.

The integrity of the genome is maintained by a host of surveillance and repair mechanisms that are pivotal for cellular function. The tumour suppressor protein p53 is a major component of the DNA damage response pathway and plays a vital role in the maintenance of cell-cycle checkpoints. Here we show that a microRNA, miR-486, and its host gene ankyrin-1 (ANK1) are induced by p53 following DNA damage. Strikingly, the cytoskeleton adaptor protein ankyrin-1 was induced over 80-fold following DNA damage. ANK1 is upregulated in response to a variety of DNA damage agents in a range of cell types. We demonstrate that miR-486-5p is involved in controlling G1/S transition following DNA damage, whereas the induction of the ankyrin-1 protein alters the structure of the actin cytoskeleton and sustains limited cell migration during DNA damage. Importantly, we found that higher ANK1 expression correlates with decreased survival in cancer patients. Thus, these observations highlight ANK1 as an important effector downstream of the p53 pathway.

Translational repression and eIF4A2 activity are critical for microRNA-mediated gene regulation.

MicroRNAs (miRNAs) control gene expression through both translational repression and degradation of target messenger RNAs (mRNAs). However, the interplay between these processes and the precise molecular mechanisms involved remain unclear. Here, we show that translational inhibition is the primary event required for mRNA degradation. Translational inhibition depends on miRNAs impairing the function of the eIF4F initiation complex. We define the RNA helicase eIF4A2 as the key factor of eIF4F through which miRNAs function. We uncover a correlation between the presence of miRNA target sites in the 3' untranslated region (3'UTR) of mRNAs and secondary structure in the 5'UTR and show that mRNAs with unstructured 5'UTRs are refractory to miRNA repression. These data support a linear model for miRNA-mediated gene regulation in which translational repression via eIF4A2 is required first, followed by mRNA destabilization.

Arylpropanolamines: selective beta3 agonists arising from strategies to mitigate phase I metabolic transformations.

Utilization of N-substituted-4-hydroxy-3-methylsulfonanilidoethanolamines 1 as selective beta(3) agonists is complicated by their propensity to undergo metabolic oxidative N-dealkylation, generating 0.01-2% of a very potent alpha(1) adrenergic agonist 2. A summary of the SAR for this hepatic microsomal conversion precedes presentation of strategies to maintain the advantages of chemotype 1 while mitigating the consequences of N-dealkylation. This effort led to the identification of 4-hydroxy-3-methylsulfonanilidopropanolamines 15 for which the SAR for the unique stereochemical requirements for binding to the beta adrenergic receptors culminated in the identification of the potent, selective beta(3) agonist 15f.

Design of novel inhibitors of aminopeptidases. Synthesis of peptide-derived diamino thiols and sulfur replacement analogues of bestatin.

Investigations were directed toward inhibition of an aminopeptidase, isolated from rat brain, which has been implicated in the metabolic inactivation of enkephalins. The design rationale and synthesis of novel peptidyl diamino thiol inhibitors of rat brain aminopeptidase are presented, along with accompanying structure-activity analysis. Some of the reported compounds are highly active aminopeptidase inhibitors and possess enzyme inhibitory potency in the nanomolar range (62; I50 = 1 nM). Analysis of the data permits speculations on possible modes of binding of diamino thiols to aminopeptidase. Other investigations were directed toward understanding the mode of enzyme binding of the naturally occurring aminopeptidase inhibitor bestatin. On the basis of published models of enzyme binding, replacement of the C-2 hydroxyl group of bestatin by a sulfhydryl group was anticipated to lead to enhanced inhibition due to a strengthened interaction of this group with enzymic zinc. Contrary to expectations, "thiobestatin" inhibited rat brain aminopeptidase with only the same degree of effectiveness as the corresponding alcohol. Speculations on the possible mode of enzyme-inhibitor binding of bestatin are offered.

Ketomethylureas. A new class of angiotensin converting enzyme inhibitors.

The design rationale for a new series of tripeptide derived angiotensin converting enzyme (ACE) inhibitors, which we term "ketomethylureas", is described. Analogs of tripeptide substrates (i.e. N-benzoyl-Phe-Ala-Pro) in which the nitrogen atom of the scissile amide bond and the adjacent asymmetric carbon atom of the penultimate amino acid residue are formally transposed give rise to this novel class of inhibitors. The most potent ketomethylureas inhibit ACE with I50 values in the nM range.

Revision of failed hip surface replacement arthroplasties with a bipolar prosthesis. Three case reports with two- to three-year follow-up observations.

Three cases of an isolated femoral component failure of a hip surface replacement were treated by use of a press-fit bipolar prosthesis to articulate with the retained acetabular cup. At two to three years post-surgery (average, 31 months), these three conversions had good clinical function and maintained an acceptable radiographic appearance. While no optimal long-term solution currently exists for failed hip surface replacements in young adults, this rather straightforward surgical conversion may have a role to play in the interim management of some of these patients.

Design of peptide derived amino alcohols as transition-state analog inhibitors of angiotensin converting enzyme.

A new amino alcohol modification designed to mimic the putative transition-state of amide bond cleavage by proteolytic enzymes has been incorporated into the scissile bond position of N-benzoyl-Phe-Ala-Pro, a known substrate of angiotensin converting enzyme (ACE). The resulting modified tripeptides (i.e. 4) are shown to be a new class of potent inhibitors of converting enzyme.

Ketomethyldipeptides I. A new class of angiotensin converting enzyme inhibitors.

The design rationale for a new series of angiotensin-converting enzyme (ACE) inhibitors which incorporate a ketone substituent into a peptide backbone is described. Molecular regions which were expected to mimic the binding of an N-acyl tripeptide substrate at secondary binding sites S1 and S1' were systematically varied in order to study the specificity of inhibitor binding and optimize inhibition against ACE. The most effective ketomethyldipeptides inhibit ACE in the 10(-9) M range.

Ketomethyldipeptides II. Effect of modifications of the alpha-aminoketone portion on inhibition of angiotensin converting enzyme.

Results of an investigation aimed at identifying the consequences of chemical modifications of the alpha-aminoketone moiety of ketomethyldipeptides on angiotensin converting enzyme (ACE) inhibition are reported. These studies lead to the conclusion that within this series, the optimal structural backbone formulation for inhibition of ACE is represented by 1. Introduction of a Sar-Pro C-terminal dipeptide in this system, in contrast to other inhibitor classes, is compatible with potent inhibitory activity. Other structure-activity relationships for ketomethyldipeptides and related derivatives are presented, and speculations on possible modes of binding of these inhibitors to ACE, and on the question of ketone rehybridization are offered.