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Query: UMLS:C0030552 (
paresis
)
5,831
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Charcot-Marie-Tooth disease (CMT), or
hereditary motor and sensory neuropathy
(
HMSN
), includes two main subtypes of CMT1/HMSN I (demyelinating), and CMT2/HMSN II (axonal). Further heterogeneity has been demonstrated by genetic molecular studies, with at least four responsible genes for CMT1. As for CMT2, a mutation in the neurofilament-light (NF-L) gene has been identified in a single family, and other CMT2 loci have been mapped. We propose a clinical classification of the CMT2 phenotypes, and review the features of the identified CMT2 genotypes. The following main subtypes of CMT2 are considered in the phenotype classification: classical CMT2, the variants of CMT2 showing atypical features that may represent either variance in the classical CMT2 phenotype or separate entities; CMT2 plus, i.e. complex forms with involvement of additional neural structures. The recognized CMT2 genotypes include: CMT2A (mapped to chromosome 1p35-36); CMT2B (3q13-22); CMT2C (with vocal cord
paresis
); CMT2D (7p14); CMT2E, related to a mutation in the NF-L gene on chromosome 8p21; proximal CMT2, or
HMSN
P (3q13.1); CMT2 with MPZ mutations; autosomal recessive CMT2 (1q21.2-q21.3); agenesis of the corpus callosum with sensorimotor neuronopathy (15q13-q15); CMT2 X-linked with deafness and mental retardation (Xq24-q26). The identified genotypes may correspond to previously described clinical subtypes of CMT2. In particular, classical CMT2 presents in association with NF-L gene mutation, in the only CMT2 family with known gene mutation, and in CMT2A patients. However, the features of classical CMT2 have been paradoxically reported also in families with MPZ mutation, and conversely several CMT2 families are not linked to the known CMT2 loci. Further cloning of the CMT2 genes will ultimately shed light on the pathogenic mechanism(s) implicated in the process of axonal degeneration, shared by the different CMT2 genotypes.
...
PMID:Charcot-Marie-Tooth disease (CMT): distinctive phenotypic and genotypic features in CMT type 2. 1123 Oct 25
Three Spanish families with an autosomal recessive severe
hereditary motor and sensory neuropathy
, showing mutations in the ganglioside-induced-differentiation-associated protein 1 (GDAP1) gene in the Charcot-Marie-Tooth (CMT) type 4A locus were studied. The disorder started in the neonatal period or early infancy with weakness and wasting of the feet and, subsequently, involvement of the hands, causing severe disability. By the late teens, some patients developed a hoarse voice and vocal cord
paresis
. Peripheral motor nerve conduction velocity (MNCV) could not be measured in many cases because of the absence of muscle response due to distal atrophy. However, latencies to proximal muscles were in the normal range; median MNCV was >40 m/s in those cases in which it could be measured. Sural nerve biopsy from two patients showed a pronounced depletion of myelinated fibres, regenerative clusters and signs of axonal atrophy. Additionally, a small proportion of thin myelinated fibres and proliferation of Schwann cells forming onion bulb structures were also found. Unmyelinated fibre population was markedly increased. These findings are indicative of a predominant axonal degeneration with some demyelinating features. These Spanish families share in the severe CMT clinical phenotype with some Tunisian families who also presented mutations in the GDAP1 gene and to which the CMT4A locus was originally assigned. However, our families differ in the presence of laryngeal involvement and values of MNCV and pathological features are more in line with CMT2 type. The possibility that GDAP1 gene mutations could be expressed under different phenotypes is a question to be resolved.
...
PMID:Clinical, electrophysiological and morphological findings of Charcot-Marie-Tooth neuropathy with vocal cord palsy and mutations in the GDAP1 gene. 1282 18
We present an acute stridor secondary to bilateral vocal cord
paresis
in a patient with demyelinating form (type I) of
hereditary motor and sensory neuropathy
(
HMSN
). Management problems are discussed and
HMSN
reviewed.
...
PMID:Hereditary motor and sensor neuropathy: a cause of acute stridor. 1611 97
Inherited neuropathies are clinically and genetically heterogeneous. At least 28 genes and 12 loci have been associated with Charcot-Marie-Tooth disease (CMT) and related inherited neuropathies. Most causes of inherited neuropathy have been discovered by positional cloning technique and in the past two years, the pace of CMT gene discovery has accelerated. Genetic studies have revealed the following gene mutations as the causes of inherited neuropathies; PMP22, MPZ, EGR2, SOX10, SIMPLE/LITAF, ARHGEF10 for CMT1 (autosomal dominant demyelinating form); GDAP1, MTMR2, SBF2/MTMR13, KIAA1985, NDRG1 PRX for CMT4 (autosomal recessive demyelinating form), MFN2, KIF1B, RAB7, GARS, NEFL, HSPB1, HSPB8 for CMT2 (autosomal dominant axonal form); LMNA, GAN1, KCC3, TDP1, APTX, SETX for AR-CMT2 (autosomal recessive axonal form); GIB1 for CMTX (X-linked CMT); DNM2 for CMT-DI (autosomal dominant CMT with intermediate nerve conduction velocities); and DHH for minifascicular neuropathy. These discovered CMT causing genes/proteins include those which show unpredictable correlations with the peripheral nervous system. However, these genes/proteins are definitely important for the peripheral nerve, and their discovery should pave the way for dramatic progress in the understanding of peripheral nerve biology. On the other hand, genotype-phenotype correlations of these genes are also important in order to understand the pathomechanisms of inherited neuropathy. Because, based on mutation studies, a large number of genes associated with both the CMT1/4 and CMT2 forms have been identified, it is usually difficult to predict the causative gene based on clinical information from patients without specific complications. To clarify the specific features and molecular mechanisms of five diseases that we previously reported, we reviewed recent progress in
HMSN
-P linked to chromosome 3, CMT4F caused by PRX, CMT4A caused by GDAP1, CMT4B2 caused by SBF2/MTMR13, and SCAN1 caused by TDP1.
HMSN
-P is characterized by late onset, proximal dominant severe muscle weakness, fasciculations, muscle cramp and sensory involvement.
HMSN
-P is a primary neuronopathy. Mutations in periaxin are associated with a broad spectrum of demyelinating neuropathies including DSS, a sensory dominant form and early onset slowly progressive CMT. Pathologically, loss of myelinated fibers, demyelination, small onion bulb formations, tomacula formation and myelin foldings were seen in sural nerves. Absence of septate like junction in the paranodal loop suggests that periaxin could be required for the adhesion complex. GDAP1 is a relatively common cause of CMT4. Half of reported patients showed the demyelinating form, while the rest showed the axonal form. The typical feature of CMT4A is
paresis
of the vocal cords and diaphragm. CMT4B2 is characterized by autosomal recessive, juvenile onset glaucoma and focally folded myelin in sural nerves. SBF2/MTMR13 mutations cause CMT4B2. Early onset glaucoma was seen in patients with nonsense mutations. SBF2/MTMR13 and MTMR2, which is the cause of CMT4B1, could be acting on the same 3-phosphoinositide signaling pathway. Clinical phenotypes of patients with TDP1, APTX, or SETX mutations share common clinical findings, namely cerebellar ataxia and axonal neuropathy. TDP1 and aprataxin both act on the single strand break repair pathway, with TDP1 working specifically on topoisomerase I related SSBR. Senataxin is a RNA helicase acting on RNA maturation and termination in yeast. Since these three proteins share a common pathway, disruption in any of them could induce a delay in the transcription process. The low rate of protein supply could lead to deaths of large neuronal cells.
...
PMID:[Molecular genetics of inherited neuropathies]. 1654 90
To clarify the specific features and molecular mechanisms of five diseases that we previously reported, we reviewed recent progress in
HMSN
-P linked to chromosome 3, CMT4F caused by PRX, CMT4A caused by GDAP1, CMT4B2 caused by SBF2/MTMR13F, and SCAN1 caused by TDP1.
HMSN
-P is characterized by late onset, proximal dominant severe muscle weakness, fasciculations, muscle cramp and sensory involvement.
HMSN
-P is a primary neuronopathy. Mutations in periaxin are associated with a broad spectrum of demyelinating neuropathies including DSS, a sensory dominant form and early onset slowly progressive CMT. Pathologically, loss of myelinated fibers, demyelination, small onion bulb formations, tomacula formation and myelin foldings were seen in sural nerves. Absence of septate like junction in the paranodal loop suggests that periaxin could be required for the adhesion complex. GDAP1 is a relatively common cause of CMT4. Half of reported patients showed the demyelinating form, while the rest showed the axonal form. The typical feature of CMT4A is
paresis
of the vocal cords and diaphragm. CMT4B2 is characterized by autosomal recessive, juvenile onset glaucoma and focally folded myelin in sural nerves. SBF2/MTMR13 mutations cause CMT4B2. Early onset glaucoma was seen in patients with nonsense mutations. SBF2/MTMR13 and MTMR2, which is the cause of CMT4B1, could be acting on the same 3-phosphoinositide signaling pathway. Clinical phenotypes of patients with SCAN1 showed cerebellar ataxia and axonal neuropathy. TDP1 acts on the single strand break repair pathway, and works specifically on topoisomerase I related SSBR. Disruption of TDP1 could induce a delay in the transcription process. The low rate of protein supply could lead to deaths of large neuronal cell.
...
PMID:[Molecular genetics of inherited neuropathies]. 1743 74
Hereditary neuropathies are classified into
HMSN
/Charcot-Marie-Tooth disease (CMT), familial amyloid polyneuropathy (FAP), hereditary motor neuropathies (HMN) and hereditary sensory (and autonomic) neuropathies (HSAN). The clinical features of
HMSN
are generally characterized as distal dominant motor and sensory involvements. However, we have reported a novel
HMSN
with proximal dominancy (HMSN-P) originated in Okinawa and Shiga prefectures, Japan. The gene locus is located in the centromere region of chromosome 3. In 2008, a new family with the
HMSN
-P was reported from Brazilians of Japanese ancestry. This Brazilian family was initially diagnosed as having "a familial ALS". The
HMSN
-P linked to ch.3 is not limited in Japan, but may be present in the worldwide. The overseas scientific research for the elucidation of the mechanism of
HMSN
-P supported by JSPS KAKENHI (21406026) is planning. Recently several other types of
HMSN
-P have been reported;
HMSN
-P with urinary disturbance and paroxysmal dry cough, a patient with both CMT 1A and mild spinal muscular atrophy and CMT1A with severe
paresis
of the proximal lower limb muscles. Therefore the clinical concept of
HMSN
is not limited as the disease with distal dominant motor sensory involvement.
HMSN
has the wider spectrum from distal to proximal and motor/sensory to autonomic neuropathies.
...
PMID:[Wide spectrum of hereditary motor sensory neuropathy (HMSN)]. 2003 Feb 57
