At least eight different
TGs, distributed in the human body, have been identified to date (Table 1) [14-19].
Table 1: TGs and their physiological
roles when known.
|
TG
|
Physiological role
|
Gene map location
|
Reference
|
|
Factor XIIIa
|
Blood clotting
|
6p24-25
|
[14]
|
|
TG 1 (Keratinocyte TG, kTG)
|
Skin differentiation
|
14q11.2
|
[15]
|
|
TG 2
(Tissue TG, tTG, cTG)
|
Apoptosis, cell adhesion, signal transduction
|
20q11-12
|
[16]
|
|
TG 3 (Epidermal TG, eTG)
|
Hair follicle differentiation
|
20p11.2
|
[17]
|
|
TG 4 (Prostate TG, pTG)
|
Suppression of sperm immunogenicity
|
3q21-2
|
[18]
|
|
TG 5 (TG X)
|
Epidermal differentiation
|
15q15.2
|
[19]
|
|
TG 6 (TG Y)
|
Central Nervous System Development
|
20p13
|
[19]
|
|
TG 7 (TG Z)
|
Unknown function
|
15q15.2
|
[19]
|
Complex gene expression
mechanisms regulate the physiological roles that these enzymes play in both the
intracellular and extracellular compartments. In the Nervous System, for
example, several forms of TGs are simultaneously expressed [20-22]. In these last
years, moreover, several alternative splice variants of TGs, mostly in the 3’-
end regions, have been identified [23]. Interestingly, some of them are
differently expressed in human pathologies, such as Alzheimer’s Disease (AD)
[24]. In addition, several MicroRNAs regulating TG2 expression both in
inflammatory and neoplastic conditions have been recently identified [25-26].
Very recently, a long non coding RNA inside the type 2 transglutaminase gene,
which tightly correlates with the expression of its transcriptional variants,
has been reported, suggesting a new possible regulatory molecular mechanism of
the TG2 gene expression [27]. On the basis of their ubiquitous expression and
their biological roles, we may speculate that the absence of these enzymes would
be lethal. However, this does not always seem to be the case, since, for
example, null mutants of the TG2 are usually phenotypically normal at birth
[12,28,29]. This result may be explained by the expression of other TGs genes
that may substitute the TG2 missing isoform, although other TGs isoform
mutations have been associated with severe phenotypes, such as lamellar
ichthyosis for TG1 isoform mutations. Bioinformatic studies have shown that the
primary structures of human TGs share some identities in only few regions, such
as the active site and the calcium binding regions. However, high sequence
conservation and, therefore, a high degree of preservation of secondary
structure among TG2, TG3 and FXIIIa indicate that these TGs all share
four-domain tertiary structures which could be similar to those of other TGs
[30].
Role of the Transglutaminases in
Neurodegenerative Diseases
Although numerous
scientific reports suggest that the transglutaminase activity is involved in
the pathogenesis of neurodegenerative diseases, to date, however, still
controversial experimental findings about the role of the TGs enzymes in these
diseases have been obtained [31-33]. Protein aggregates in affected brain
regions are histopathological hallmarks of many neurodegenerative diseases
[34]. More than 30 years ago Selkoe et al. [35] suggested that TG activity
might contribute to the formation of protein aggregates in AD brain. In support
of this hypothesis, tau protein has been shown to be an excellent in vitro substrate
of TGs [36,37] and GGEL cross-links have been found in the neurofibrillary
tangles and paired helical filaments of AD brains [38]. Interestingly, a recent
work showed the presence of bis g-glutamyl putrescine in human CSF, which
was increased in Huntington’s Disease (HD) CSF [39]. This is an important
evidence that protein/peptides crosslinking by polyamines does indeed occur in
the brain, and that this is increased in HD brain. TGs activity has been shown
to induce also amyloid b-protein oligomerization [40] and
aggregation at physiologic levels [39]. By these molecular mechanisms, TGs
could contribute to AD symptoms and progression [41]. Moreover, there is
evidence that TGs also contribute to the formation of proteinaceous deposits in
Parkinson’s Disease (PD) [42,43], in supranuclear palsy [44,45] and in HD, a
neurodegenerative disease caused by a CAG expansion in the affected gene [46].
For example, expanded polyglutamine domains have been reported to be substrates
of TG2 [47-49] and therefore aberrant TGs activity could contribute to
CAG-expansion diseases, including HD (Figure 3). However, although all these
studies suggest the possible involvement of the TGs in the formation of
deposits of protein aggregates in neurodegenerative diseases, they do not
indicate whether aberrant TGs activity per se directly determines the disease
progression. For example, several experimental findings reported that TG2
activity in vitro leads to the formation of soluble aggregates of a-synuclein [50] or
polyQ proteins [51,52]. To date, as previously reported, at least ten human
CAG-expansion diseases have been described (Table 2) [53-62] and in at least
eight of them their neuropathology is caused by the expansion in the number of
residues in the polyglutamine domain to a value beyond 35-40.

Figure
3: Possible physiopathological effects of the mutated
huntingtin. Some of the physiopathological roles of mutated huntingtin,
including the formation of nuclear inclusions, have been described in the
Figure. AP2 = adipocyte Protein 2; BAX = bcl-2-like protein 4; BDNF =
brain-derived neurotrophic factor; CALM = calmodulin; CASP = caspases; CASP3 =
caspase 3; CASP8 = caspase 8; CBP = CREB binding protein; CBS =
cystathionine-?-synthase; DCTN1 = dynactin subunit 1; GAPD =
glyceraldehyde-3-phosphate dehydrogenase; GRB2 = growth factor receptor-bound
protein 2; HAP1 = huntingtin associated protein 1; HIP1 = huntingtin
interacting protein 1; HIP2 = huntingtin interacting protein 2; Hippi =; HIP1
protein interactor; NCOR1 = nuclear receptor corepressor 1; RasGAP = p21Ras
protein and GTPase-activating protein complex; TGs = transglutaminases; TP53 =
tumor protein 53.
Table 2: List of polyglutamine
(CAG-expansion) diseases.
|
Disease
|
Sites
of neuropathology
|
CAG
triplet number
|
Gene
product
(Intracellular
localization of
protein deposits)
|
Reference
|
|
Normal
|
Disease
|
|
Corea Major or
Huntington’s Disease
(HD)
|
Striatum (medium spiny neurons)
and cortex in late stage
|
6–35
|
36–121
|
Huntingtin(n,c)
|
[53]
|
|
Spinocerebellar Ataxia
Type 1 (SCA1)
|
Cerebellar cortex (Purkinje
cells), dentate nucleus and brain stem
|
6–39
|
40–81
|
Ataxin-1(n,c)
|
[54]
|
|
Spinocerebellar Ataxia Type 2
(SCA2)
|
Cerebellum, pontine nuclei,
substantia nigra
|
15–29
|
35–64
|
Ataxin–2 (c)
|
[55]
|
|
Spinocerebellar Ataxia Type 3
(SCA3) or Machado-Joseph disease (MJD)
|
Substantia nigra, globus pallidus,
pontine nucleus, cerebellar cortex
|
13–42
|
61–84
|
Ataxin –3 (c)
|
[56]
|
|
Spinocerebellar Ataxia Type 6
(SCA6)
|
Cerebellar and mild brainstem
atrophy
|
4–18
|
21–30
|
Calcium channel Subunit (? 1A)(m)
|
[57]
|
|
Spinocerebellar Ataxia Type 7
(SCA7)
|
Photoreceptor and bipolar cells,
cerebellar cortex, brainstem
|
7–17
|
37–130
|
Ataxin-7 (n)
|
[58]
|
|
Spinocerebellar Ataxia Type 12
(SCA12)
|
Cortical, cerebellar atrophy
|
7–32
|
41–78
|
Brain specific regulatory subunit
of protein phosphatase PP2A (?)
|
[59]
|
|
Spinocerebellar Ataxia Type 17
(SCA17)
|
Gliosis and neuronal loss in the
Purkinje cell layer
|
29–42
|
46–63
|
TATA-binding protein (TBP) (n)
|
[60]
|
|
Spinobulbar Muscular Atrophy
(SBMA) or Kennedy Disease
|
Motor neurons (anterior horn
cells, bulbar neurons) and dorsal root ganglia
|
11–34
|
40–62
|
Androgen receptor (n, c)
|
[61]
|
|
Dentatorubralpallidoluysian
Atrophy (DRPLA)
|
Globus pallidus, dentato-rubral
and subthalamic nucleus
|
7–35
|
49–88
|
Atrophin (n, c)
|
[62]
|
|
Cellular localization: c, cytosol;
m, membrane; n, nucleus
|
Remarkably, the mutated
proteins have no obvious similarities except for the expanded polyglutamine
domain. In fact, in all cases except SCA 12, the mutation occurs in the coding
region of the gene. However, in SCA12, the CAG triplet expansion occurs in the
untranslated region at the 5' end of the PPP2R2B gene. It has been proposed
that the toxicity results from overexpression of the brain specific regulatory
subunit of protein phosphatase PP2A [59]. Most of the mutated proteins are widely
expressed both within the brain and elsewhere in the body. A major challenge
then is to understand why the brain is primarily affected and why different
regions within the brain are affected in the different CAG-expansion diseases,
i.e., what accounts for the neurotoxic gain of function of each protein and for
a selective vulnerability of each cell type. Possibly, the selective
vulnerability [63] may be explained in part by the susceptibility of the
expanded polyglutamine domains in the various CAG-expansion diseases to act as
cosubstrates for brain TGs (Figure 4). To strengthen the possible central role
of the TGs in neurodegenerative diseases, a study by Hadjivassiliou et al. [64]
showed that anti-TG2 IgA antibodies are present in the gut and brain of patients
with gluten ataxia, a non-genetic sporadic cerebellar ataxia, but not in ataxia
control patients. Recently, anti-TG2, -TG3 and - TG6 antibodies have been found
in sera from Celiac Disease patients, suggesting a possible involvement also of
other TGs in the pathogenesis of dermatitis herpetiformis and gluten ataxia,
two frequent extra intestinal manifestations of gluten sensitivity [65,66].
These last findings could suggest also a possible role of the “gut-brain axe”
for the etiopathogenesis of human neurodegenerative diseases, in which the TGs
enzymes, in particular the TG2 enzyme, could play an important role [67-69]. In
support of the hypothesis of the toxic effect of TGs activity in other
neurodegenerative diseases, such as Alzheimer’s disease and Parkinson’s
Disease, TG activity has been shown to induce amyloid beta-protein and a-synuclein
oligomerization and aggregation at physiologic levels [70-72]. In fact, TGs
activity induces protofibril-like amyloid betaprotein assemblies that are
protease-resistant and inhibit long-term potentiation [41]. Therefore, by these
molecular mechanisms, TGs activity could also contribute to Alzheimer's disease
symptoms and progression. Recently, TG2 and its product isopeptide have been
found increased in Alzheimer’s disease and APPswe/PS1dE9 double transgenic mice
brains [73], while catalytically active TG2 colocalizes with Ab pathology in
Alzheimer’s disease mouse models [74].
Interestingly, other
works are suggesting that also other TGs could be involved in the molecular
mechanisms responsible for neurodegenerative diseases [75]. In particular, a
work by Basso et al. [76] found that in addition to TG2, TG1 gene expression
level is significantly induced following stroke in vivo or due to oxidative
stress in vitro. Moreover, structurally diverse inhibitors, used at
concentrations that inhibit TG1 and TG2 simultaneously, are neuroprotective.
Together, these last studies suggested that multiple TG isoforms, not only TG2,
participate in oxidative stress-induced cell death signalling, and that isoform
nonselective inhibitors of TGs will be most efficacious in combating oxidative
death in neurological disorders. These are interesting and worthwhile studies,
suggesting that multiple TGs isoforms can participate in neuronal death
processes. Therefore, all these studies suggest that the involvement of brain
TGs could represent a common denominator in several neurological diseases,
which can lead to the determination of pathophysiological consequences through
different molecular mechanisms.

Figure
4: Possible mechanisms responsible for protein aggregate
formation catalyzed by TGs. Transglutaminase activity could produce insoluble
aggregates both by the formation of Ne-(g-L-glutamyl)-L-lysine
(GGEL) isopeptide bonds (left side of the figure) and by the formation of
N,N-bis-(g-L-glutamyl)polyamine
bridges (right side of the figure) in the mutated huntingtin.