Retraction notice to Plexin-B1 and Semaphorin 4D Cooperate to Promote Perineural Invasion in a RhoA/ROK-Dependent Manner Am J Pathol 180 (2012) 1232-1242.

This article has been retracted: please see Elsevier Policy on Article Withdrawal (https://www.elsevier.com/about/our-business/policies/article-withdrawal). This article is being retracted following correspondence from the Office of Accountability and Compliance at the University of Maryland, Baltimore. An internal investigation into this manuscript by the University of Maryland, Baltimore, found evidence that there are errors with the presentation of the standard deviations and statistical significance shown in Figure 6 which are not supported by the original data, and that these inaccuracies warrant retraction to correct the scientific record. Despite extensive efforts, the journal was unable to contact Dr. Ying-hua Yang and Dr. Hua Zhou with regard to this retraction.

Is the "lactormone" a key-factor for exercise-related neuroplasticity? A hypothesis based on an alternative lactate neurobiological pathway.

For many years lactate was seen as a metabolite from glucose metabolism. However, since the last century researchers have shown that this molecule has an important role on liver, muscle, and brain metabolism. Lactate traffics along whole body mediating many biological processes depending on specific situations. For example, glucose is the main substrate used during exercise but lactate released by striated skeletal muscle is used by own muscle as secondary fuel. On the other hand, neuronal firing in the brain is almost totally lactate-dependent. In addition, lactate has an important role on BDNF-mediated neuroplasticity. As this molecule has a pleiotropic role in the body, it was called as "lactormone" in 2009. Here we show basic concepts on peripheral and central metabolism and discuss neurobiological pathways of lactate, including an alternative hypothesis on lactate released during exercise.

Brown and White Adipose Tissue Expression of IL6, UCP1 and SIRT1 are Associated with Alterations in Clinical, Metabolic and Anthropometric Parameters in Obese Humans.

Aim: The present study aimed to analyze the expression of IL6, UCP1 and SIRT1 in adipose tissue (WAT and BAT) in association to clinical, metabolic and anthropometric parameters in obese humans. Methods: WAT and BAT samples from obese patients (n=27) were collected. IL6, UCP1 and SIRT1 markers were measured by qRT-PCR. The association between IL6, UCP1 and SIRT1 mRNA expression and anthropometric and clinical parameters were evaluated, using appropriate statistical tests. Results: Our results demonstrated that high levels of IL6 are associated with altered glucose levels in the WAT (p=0.01). In contrast, high levels of IL6 in the BAT were associated with decreased % fat (p=0.01) and fat weight (p=0.02) and increased mVO2 (p=0.02) and VO2 (p=0.02). For UCP1, a higher expression in the BAT was observed when compared to the WAT (p=0.0001). This gene expression was associated with lower values of BMI (p=0.03), % fat (P=0.02) and fat weight (P=0.02) and increased mVO2 (p=0.041) and VO2 (p=0.001). In the WAT, decreased levels of SIRT1 were associated with increased fat weight (p=0.02); in the BAT, associations were found for % fat (p=0.018) and mVO2 (p=0.03). Conclusion: These results reveal different characteristics in the biological actions between WAT and BAT in obese humans. Increased levels of IL6, UCP1 and SIRT1 in the BAT were associated with metabolic parameters improvements.