82 Etiopathogenesis of Cruciate Ligament Rupture
L-arginineO 2 , NADPHH 2 O, NADP+ iNOS, cNOSN-hydroxy-L-arginineiNOS, cNOSO 2 , 1/2 equiv NADPHH 2 O, 1/2 equiv NADP+L-citrulline + NOFigure 10.1 Production of nitric oxide via the oxidation
of L-arginine by a family of nitric oxide synthase (NOS)
enzymes.
suppresses different cellular protein synthesis
in various cell types, and produces marked
cytotoxicity by inhibiting mitochondrial respi-
ration or inducing DNA alterations. Reaction
of NO with the superoxide anion (O 2 .–),
another product of activated macrophages,
may yield peroxynitrite (ONOO–) which medi-
ates oxidative DNA damage and subsequently
programmed cell death described for several
cell types, including chondrocytes (Del Carlo &
Loeser 2002).
The list of diseases where iNOS is currently
thought to be involved is large and rapidly
increasing. In multiple organ failure following
septic shock, type I diabetes or ulcerative col-
itis, massive NO formation due to iNOS acti-
vation was characterized. Another chronic local
inflammatory process with iNOS participation
occurs in the arthritic joint (Del Carlo & Loeser
2008).
Nitric oxide activity in articular tissues
Apart from iNOS, the isoforms cNOS and
nNOS which produce lower amounts of NO,
have also been detected in different healthy and
osteoarthritic joint tissues (Aminet al. 1995; Pel-
letieret al. 2000; Di Mauroet al. 2006). However,
nNOS was more frequently expressed in nor-
mal than in osteoarthritis (OA) chondrocytes
(Rosaet al. 2008). Within joints, NO is mainly
produced by superficial cartilage chondrocytes
and by synoviocytes or macrophages in the
inflamed synovial membrane; all cells in which
iNOS expression is upregulated during OA
(Aminet al. 1995; Hauselmann ̈ et al. 1998).
The importance of iNOS expression and the
subsequent increase of NO in the pathogenesis
of OA is endorsed by experiments in vivo
demonstrating that specific inhibition of iNOS
results in decreased production of cytokines,
matrix metalloproteinases (MMPs) and per-
oxynitrite (Pelletieret al. 1999). Furthermore,
ex vivostudies demonstrated that the canine
cranial cruciate ligament (CrCL) actively pro-
duces NO mainly derived from the inducible
NOS pathway (Sprenget al. 2000), suggesting
that ligament fibroblasts are actively involved
in extracellular matrix (ECM) homeostasis.
Additionally, the activation of CrCL with a pro-
inflammatory mixture of lipopolysaccharide
(LPS)/IL-1/TNF leads to increased NO produc-
tion and iNOS activity, indicating that ligament
fibroblasts indeed produce substantial amounts
of NO under a specific stimulus (Louiset al.
2006).
Upon exposure to pro-inflammatory
cytokines, including IL-1β, IL-17, TNFα,
IFNγ, and LPS, as well as to shear stress, iNOS
expression is upregulated, resulting in an
increased NO production that perpetuates the
release of inflammatory cytokines and other
catabolic processes.
As assessment of the unstable NO is
extremely difficult, NO production must
be calculated by measuring its stable end
products nitrite or nitrate. In ligament tissue,
especially in partially or totally ruptured CrCL,
the assessment of NO production is difficult.
Specimens of naturally diseased CrCL are
usually retrieved from canine patients during
surgical repair, leading to the problem that
highly traumatized tissue is examined without
knowing if a measured production of NO and
NO metabolites is triggered by the original
CrCL pathology, or is only a consequence of
the mechanical trauma of ligament disruption.
Interestingly, normal CrCL produces more NO
compared to torn CrCL, normal cartilage or
normal medial collateral ligaments of the stifle
in dogs (Sprenget al. 2000)