Biologically active compound conjugated to a stapled or stitched peptide

[0001] The present invention relates to improvements in drug delivery. [0002] More particularly it relates to the use of Cell Penetrating Agents (CPA’s), and more particularly still to the use of Cell Penetrating Peptides (CPP’s) which have been stabilized 5 by, for example: i) stapling two amino acids to form Stapled CPP’s (StaP’s) or ii) stitching three or more amino acids to form stitched CPP’s (StiP’s). [0003] These stabilized CPP’s are conjugated to a drug or Biologically Active Compound (BAC) directly or via a Bi-Functional Linker (BFL) so that the BAC can be carried though a cell membrane by the CPP. The resulting molecules are referred to as Drug Carrying Cell 10 Penetrating Molecules (DCCPM’s). [0004] The preferred BAC’s delivered in this manner are oligonucleotides (ON’s), more preferably still electrically low charge carrying oligonucleotides (charge -3 to +3 at pH 7.5) and most preferably electrically neutral oligonucleotides (charge -1 to +1 at pH 7.5), such as, but not limited to, polynucleic acids (PNAs), phosphorodiamidate morpholino oligonucleotides (PMO’s) 15 or modified derivatives thereof. [0005] The preferred BFL may be PEGylated, comprising poly ethylene glycol (PEG) groups including modifications such as an amine group, or incorporate a spacer, such as -Ala. These modifications can improve solubilisation or provide appropriate spacing between functional moieties. 20 [0006] The invention also relates to a method of facilitating the uptake of a BAC into a cell, the use of a DCCPM in the treatment of a disease requiring alteration of an endogenous or exogenous gene, a method of improving the bioavailability of a drug or BAC, a method of introducing a drug or BAC to a site which is refractory to the drug or BAC in its native state, a method of treating a subject comprising administering the DCCPM’s of the invention and to a 25 pharmaceutical composition comprising the DCCPM and one or more pharmaceutically acceptable excipients. [0007] Still further aspects will be apparent from the detailed description

Development of antisense-mediated myostatin knockdown for the treatment of insulin resistance

Myostatin is a negative regulator of muscle mass and its inhibition represents a promising strategy for the treatment of muscle disorders and type 2 diabetes. However, there is currently no clinically effective myostatin inhibitor, and therefore novel methods are required. We evaluated the use of antisense phosphorodiamidate morpholino oligomers (PMO) to reduce myostatin expression in skeletal muscle and measured their effects on muscle mass and glucose uptake. C57/Bl6 mice received intramuscular or intravenous injections of anti-myostatin PMOs. Repeated intramuscular administration lead to a reduction in myostatin transcript levels (~ 20–40%), and an increase in muscle mass in chow and high-fat diet (HFD)-fed mice, but insulin-stimulated glucose uptake was reduced in PMO-treated muscles of HFD-fed mice. Five weekly intravenous administrations of 100 nmol PMO did not reduce myostatin expression, and therefore had no significant physiological effects. Unexpectedly, exon skipping levels were higher after intramuscular administration of PMO in HFD- than chow-fed mice. These results suggest that a modest PMO-induced reduction in myostatin transcript levels is sufficient to induce an increase in muscle mass, but that a greater degree of inhibition may be required to improve muscle glucose uptake

Local myostatin inhibition improves skeletal muscle glucose uptake in insulin resistant high fat diet-fed mice

Myostatin inhibition is thought to improve whole body insulin sensitivity and mitigate the development of insulin resistance in models of obesity. However, although myostatin is known to be a major regulator of skeletal muscle mass, the direct effects of myostatin inhibition in muscle on glucose uptake and the mechanisms which may underlie this are still unclear. We investigated the effect of local myostatin inhibition by adeno-associated virus-mediated overexpression of the myostatin pro-peptide on insulin-stimulated skeletal muscle glucose disposal in chow-fed or high fat diet-fed mice and evaluated the molecular pathways that might mediate this. We found that myostatin inhibition improved glucose disposal in obese high fat diet-fed mice alongside the induction of muscle hypertrophy, but did not have an impact in chow-fed mice. This improvement was not associated with greater glucose transporter or peroxisome proliferator-activated receptor gamma coactivator-1α expression or 5' AMP-activated protein kinase activation as previously suggested. Instead, transcriptomic analysis suggested that the improvement in glucose disposal was associated with significant enrichment in genes involved in fatty acid metabolism and translation of mitochondrial genes. Thus, myostatin inhibition improves muscle insulin-stimulated glucose disposal in obese high fat diet-fed mice independent of muscle hypertrophy, potentially involving previously unidentified pathways

Hippocampal synaptic and membrane function in the DBA/2J-mdx mouse model of Duchenne muscular dystrophy

Dystrophin deficiency is associated with alterations in cell physiology. The functional consequences of dystrophin deficiency are particularly severe for muscle physiology, as observed in Duchenne muscle dystrophy (DMD). DMD is caused by the absence of a 427 kDa isoform of dystrophin. However, in addition to muscular dystrophy symptoms, DMD is frequently associated with memory and attention deficits and epilepsy. While this may be associated with a role for dystrophin in neuronal physiology, it is not clear what neuronal alterations are linked with DMD. Our work shows that CA1 pyramidal neurons from DBA/2J-mdx mice have increased afterhyperpolarization compared to WT controls. All the other electrotonic and electrogenic membrane properties were unaffected by this genotype. Finally, basal synaptic transmission, short-term and long-term synaptic plasticity at Schaffer collateral to CA1 glutamatergic synapses were unchanged between mdx and WT controls. These data show that the excitatory component of hippocampal activity is largely preserved in DBA/2J-mdx mice. Further studies, extending the investigation to the inhibitory GABAergic function, may provide a more complete picture of the functional, network alterations underlying impaired cognition in DMD. In addition, the investigation of changes in neuronal single conductance biophysical properties associated with this genotype, is required to identify the functional alterations associated with dystrophin deficiency and clarify its role in neuronal function

Training modalities: impact on endurance capacity

Endurance athletes demonstrate an exceptional resistance to fatigue when exercising at high intensity. Much research has been devoted to the contribution of aerobic capacity for the economy of endurance performance. Important aspects of the fine-tuning of metabolic processes and power output in the endurance athlete have been overlooked. This review addresses how training paradigms exploit bioenergetic pathways in recruited muscle groups to promote the endurance phenotype. A special focus is laid on the genome-mediated mechanisms that underlie the conditioning of fatigue resistance and aerobic performance by training macrocycles and complements. The available data on work-induced muscle plasticity implies that different biologic strategies are exploited in athletic and untrained populations to boost endurance capacity. Olympic champions are probably endowed with a unique constitution that renders the conditioning of endurance capacity for competition particularly efficient

CaMKII content affects contractile, but not mitochondrial, characteristics in regenerating skeletal muscle

Background The multi-meric calcium/calmodulin-dependent protein kinase II (CaMKII) is the main CaMK in skeletal muscle and its expression increases with endurance training. CaMK family members are implicated in contraction-induced regulation of calcium handling, fast myosin type IIA expression and mitochondrial biogenesis. The objective of this study was to investigate the role of an increased CaMKII content for the expression of the contractile and mitochondrial phenotype in vivo. Towards this end we attempted to co-express alpha- and beta-CaMKII isoforms in skeletal muscle and characterised the effect on the contractile and mitochondrial phenotype. Results Fast-twitch muscle m. gastrocnemius (GM) and slow-twitch muscle m. soleus (SOL) of the right leg of 3-month old rats were transfected via electro-transfer of injected expression plasmids for native α/β CaMKII. Effects were identified from the comparison to control-transfected muscles of the contralateral leg and non-transfected muscles. α/β CaMKII content in muscle fibres was 4-5-fold increased 7 days after transfection. The transfection rate was more pronounced in SOL than GM muscle (i.e. 12.6 vs. 3.5%). The overexpressed α/β CaMKII was functional as shown through increased threonine 287 phosphorylation of β-CaMKII after isometric exercise and down-regulated transcripts COXI, COXIV, SDHB after high-intensity exercise in situ. α/β CaMKII overexpression under normal cage activity accelerated excitation-contraction coupling and relaxation in SOL muscle in association with increased SERCA2, ANXV and fast myosin type IIA/X content but did not affect mitochondrial protein content. These effects were observed on a background of regenerating muscle fibres. Conclusion Elevated CaMKII content promotes a slow-to-fast type fibre shift in regenerating muscle but is not sufficient to stimulate mitochondrial biogenesis in the absence of an endurance stimulus