Novel DMRT1 3'UTR+11insT mutation associated to XY partial gonadal dysgenesis / Nova mutação 3'UTR+11insT no gene DMRT1 associada à disgenesia gonadal parcial XY

The Y-chromosome-located SRY gene encodes a small testis-specific protein containing a DNA-binding motif known as the HMG (high mobility group) box. However, mutations in SRY are not frequent especially in cases of 46,XY partial gonadal dysgenesis. Several sex-determining genes direct the fate of the bipotential gonad to either testis or ovary. In addition, heterozygous small deletions in 9p can cause complete and partial XY gonadal dysgenesis without other symptoms. Human DMRT1 gene, which is located at 9p24.3, is expressed in testis and ovary and has been considered, among others, a candidate autosomal gene responsible for gonadal dysgenesis. In this report we describe a nucleotide insertion in DMRT1 3'UTR in a patient of XY partial gonadal dygenesis. The 3'UTR+11insT is located within a conserved motif important for mRNA stabilization.

O gene SRY, localizado no cromossomo Y, codifica uma proteína testículo-específica contendo um domínio HMG (grupo de alta mobilidade) de ligação ao DNA. No entanto, mutações no gene SRY não são frequentes, especialmente nos casos de disgenesia gonadal parcial em indivíduos 46,XY. São atualmente conhecidos vários genes que participam do processo de diferenciação gonadal, tanto para o desenvolvimento testicular quanto para o ovariano. Além disso, pequenas deleções heterozigotas em 9p podem causar disgenesia gonadal XY completa ou parcial, sem outros sintomas associados. O gene DMRT1 humano, que está localizado em 9p24.3, é expresso no testículo e ovário no período fetal e tem sido considerado um dos genes autossômicos envolvido na etiologia das disgenesias gonadais. Neste trabalho, descrevemos a inserção de um nucleotídeo em 3'UTR do gene DMRT1 em um paciente 46,XY com disgenesia gonadal parcial. A mutação 3'UTR+11insT está localizada dentro de um motivo conservado importante para a estabilização do mRNA.

Novel DMRT1 3'UTR+11insT mutation associated to XY partial gonadal dysgenesis.

The Y-chromosome-located SRY gene encodes a small testis-specific protein containing a DNA-binding motif known as the HMG (high mobility group) box. However, mutations in SRY are not frequent especially in cases of 46,XY partial gonadal dysgenesis. Several sex-determining genes direct the fate of the bipotential gonad to either testis or ovary. In addition, heterozygous small deletions in 9p can cause complete and partial XY gonadal dysgenesis without other symptoms. Human DMRT1 gene, which is located at 9p24.3, is expressed in testis and ovary and has been considered, among others, a candidate autosomal gene responsible for gonadal dysgenesis. In this report we describe a nucleotide insertion in DMRT1 3'UTR in a patient of XY partial gonadal dygenesis. The 3'UTR+11insT is located within a conserved motif important for mRNA stabilization.

Activity of an antimicrobial peptide mimetic against planktonic and biofilm cultures of oral pathogens.

Antimicrobial peptides (AMPs) are naturally occurring, broad-spectrum antimicrobial agents that have recently been examined for their utility as therapeutic antibiotics. Unfortunately, they are expensive to produce and are often sensitive to protease digestion. To address this problem, we have examined the activity of a peptide mimetic whose design was based on the structure of magainin, exhibiting its amphiphilic structure. We demonstrate that this compound, meta-phenylene ethynylene (mPE), exhibits antimicrobial activity at nanomolar concentrations against a variety of bacterial and Candida species found in oral infections. Since Streptococcus mutans, an etiological agent of dental caries, colonizes the tooth surface and forms a biofilm, we quantified the activity of this compound against S. mutans growing under conditions that favor biofilm formation. Our results indicate that mPE can prevent the formation of a biofilm at nanomolar concentrations. Incubation with 5 nM mPE prevents further growth of the biofilm, and 100 nM mPE reduces viable bacteria in the biofilm by 3 logs. Structure-function analyses suggest that mPE inhibits the bioactivity of lipopolysaccharide and binds DNA at equimolar ratios, suggesting that it may act both as a membrane-active molecule, similar to magainin, and as an intracellular antibiotic, similar to other AMPs. We conclude that mPE and similar molecules display great potential for development as therapeutic antimicrobials.

The expression of neurokinin-1 and preprotachykinin-1 in breast cancer cells depends on the relative degree of invasive and metastatic potential.

Breast cancer has a predilection for metastasis to the bone marrow. The preprotachykinin-I (PPT-I) gene has a central role in the early migration of breast cancer cells into the bone marrow, making this organ a latent repository of the cancer cells. This study investigated whether the invasive and metastatic potential of breast cancer cells correlate with the expression of the PPT-I gene and the receptors for its peptides, neurokinin-1 (NK-1) and NK-2. The studies compared cells that are non-tumorigenic (MCF12A), low metastatic and invasive potential (MCF7), and sublines of MCF with increased invasive and metastatic potential (LCC1 and LCC2). LCC2, but not LCC1 is tamoxifen resistant. Quantitative RT-PCR showed increased expression of PPT-I, NK-1 and NK-2 mRNA LCC1 and LCC2. MCF7 required stimulation by phorbol ester for NK-1 induction. The levels of NK-2 mRNA were significantly increased in LCC2. Clonogenic assays with specific receptor antagonists showed a predominant role for NK-2 in the proliferation of both LCC1 and LCC2. While the growth rate of LCC1 and LCC2 were similar, the latter showed increased migration. Use of a nude mouse model confirmed higher metastatic potential of LCC2, including increased migration to regions of the endosteum. Overall, these studies show a correlation between three neuroendocrine-related genes: PPT-I, NK-1 and NK-2 and the metastatic potential of specific breast cancer cells. These cells provide a model for future studies on bone marrow metastasis.

Bone marrow stroma influences transforming growth factor-beta production in breast cancer cells to regulate c-myc activation of the preprotachykinin-I gene in breast cancer cells.

Breast cancer cells (BCCs) have preference for the bone marrow (BM). This study used an in vitro coculture of BCCs and BM stroma to represent a model of early breast cancer metastasis to the BM. The overarching hypothesis states that once BCCs are in the BM, microenvironmental factors induce changes in the expression of genes for cytokines and preprotachykinin-I (PPT-I) in both BCCs and stromal cells. Consequently, the expression of both PPT-I and cytokines are altered to facilitate BCC integration within BM stroma. Cytokine and transcription factor arrays strongly suggested that transforming growth factor-beta (TGF-beta) and c-myc regulate the expression of PPT-I so as to facilitate BCC integration among stroma. Northern analyses and TGF-beta bioassays showed that stromal cells and BCCs influence the level of PPT-I and TGF-beta in each other. In cocultures, PPT-I and TGF-beta expressions were significantly (P < 0.05) increased and decreased, respectively. TGF-beta and PPT-I were undetectable in separate stromal cultures but were expressed as cocultures. Two consensus sequences for c-myc in the 5' flanking region of the PPT-I gene were shown to be functional using gel shift and reporter gene assays. Mutagenesis of c-myc sites, neutralization studies with anti-TGF-beta, and transient tranfections all showed that c-myc is required for TGF-beta-mediated induction of PPT-I in BCCs. TGF-beta was less efficient as a mediator of BCC integration within stroma for c-myc-BCCs. Because the model used in this study represents BCC integration within BM stroma, these studies suggest that TGF-beta is important to the regulation of PPT-I in the early events of bone invasion by BCCs.