Feline Leukemia Virus Infection - A Review
Daniel Iyer, DVM,
Bruce E. LeRoy, DVM, PhD, Kenneth S. Latimer, DVM, PhD, and Holly
Moore, DVM
Class of 2005 (Iyer) and Department of Pathology (LeRoy, Latimer,
Moore) College of Veterinary Medicine, University of Georgia, Athens,
GA 30602-7388
Introduction
Feline leukemia virus (FeLV) infection is still an important cause
of morbidity in cats despite the development and use of FeLV vaccine.
There are many syndromes that are caused by FeLV viral infection. Persistent
FeLV infection can cause severe immunosuppression, severe non-regenerative
anemia, and a variety of neoplasms. FeLV is distributed worldwide.
The domestic cat is the predominant host, but the virus can also infect
other felidae.
Etiology and Epidemiology
FeLV is a retrovirus in the family Oncovirinae. Many other diseases
are caused by oncoviruses besides cancer including degenerative, proliferative,
and immunologic disorders.
There are 3 main subtypes of FeLV that have been designated FeLV-A,
FeLV-B, and FeLV-C. These viral subtypes may act alone or in combination
to cause diverse disease processes. Specific core proteins and antigens
on the virus envelope are used to differentiate these viral subtypes.
FeLV-positive cats can be infected with one, two, or all three types:
- FeLV-A occurs in all FeLV-infected cats and causes severe immunosuppression.
- FeLV-B occurs in about 50% of all FeLV-infected cats and causes neoplastic
diseases more often than in cats infected only with FeLV-A.
- FeLV-C occurs in about 1% of FeLV-infected cats and causes severe
anemia.
Most cats are infected with FeLV-A, but other subtypes also may be
found. Coinfection with FeLV-B is found in 50% of infected cats with
FeLV-A. FeLV-C coinfection may be observed with FeLV-A and, in some
instances, with both A and B subtypes.
FeLV Testing and Viral Transmission
Currently available serologic tests only identify FeLV infection and
not the specific subtype of virus(es) that are present. The rate of
FeLV infection is directly related to the population density of cats;
therefore, multicat households and catteries are most susceptible to
viral infection due to the increased density of individuals. About
1-2% of apparently healthy stray cats are actually persistently viremic.
These cats probably serve as the primary reservoir of FeLV. These carriers
excrete the FeLV in saliva, urine, feces, and tears, with saliva and
urine being the primary routes of spread. Cats housed indoors are less
likely to contract this infection. Indoor/outdoor cats increase their
chances of FeLV infection because biting serves as an efficient mode
of viral transmission.
Age resistance is an important factor as young kittens are more susceptible
to FeLV infection than are older cats. The virus envelope is very fragile
and prolonged contact between cats may be necessary to initiate viral
infection. The chances of FeLV infection also are increased by exposure
to large numbers of viral particles. FeLV can be transmitted horizontally
(by secretions and excretions) or vertically (in utero or
transmammary).
Neutralizing Antibodies and Membrane Antigens
The major envelope glycoprotein (gp70) varies with the subtype of
FeLV. This protein is used to bind to target cells. In the case of
FeLV-A, The virus binds to T lymphocytes. Therefore, antibodies directed
toward the gp 70 protein result in neutralization of the virus and
provide host immunity to reinfection with the virus.
Feline oncornavirus cell membrane antigen (FOCMA) is present on the
cell membranes of malignant cells and is not found on non-transformed
cells, even if they are infected with FeLV. It is theorized that antibodies
directed at the FOCMA will enable cats to resist the development of
leukemia and lymphoma regardless of viremia.
Pathogenesis and Clinicopathologic Findings
FeLV enters the
cat’s body though oronasal inoculation and travels
to the oropharyngeal lymph tissue for viral replication. At this point,
there can be an effective immune or ineffective response. If an effective
immune response occurs, FeLV is cleared and there is no further illness.
If an ineffective immune response occurs, the virus will be carried
to the spleen, lymph nodes, epithelial cells of the intestine and bladder,
salivary glands, and bone marrow by infected mononuclear cells in the
peripheral blood. At this point, a partially effective or ineffective
immune response can occur in the bone marrow. A partially effective
immune response will keep the virus latent in the marrow. Viremia will
not occur and FeLV will not replicate. However, this situation may
lead to the development of hematopoietic malignancy in a cat that is
FeLV-negative on serology. In the absence of an immune response, the
provirus may cause a persistent viremia (40%). This scenario may result
in an apparently healthy cat that is a carrier of viral infection or
in an active FeLV infection that is FeLV-positive on serology. Viremia
is usually evident 2-4 weeks after FeLV infection. Persistently viremic
cats develop fatal diseases after a variable time period. Approximately
50% of persistently viremic cats die within 1 year of FeLV infection,
while 83% of apparently healthy cats with FeLV infection die within
3.5 years of viral detection.
Various disorders caused by FeLV are grouped into cytoproliferative
and cytosuppressive diseases. Patient outcome is governed by the specific
FeLV subtype, the age of the cat at the time of infection, immune status
of the cat, and the particular genotype of the cat in question. Persistently
viremic cats may manifest single or multiple disease processes including
the following:
- Malignant
lymphoma (Fig. 1) is often associated
with FeLV infection. Most cases of feline lymphoma are caused by
this retrovirus, which initiates activation of proto-oncogenes
such as myc.
There are numerous subtypes of lymphoma, such as thymic lymphoma
(usually in young cats <3 years old). Alimentary lymphoma
occurs in older cats and may involve the liver, spleen, intestines,
and or lymph nodes.
Multicentric lymphoma primarily occurs in mature cats and involves
many organs. Finally, unclassified lymphoma is represented by an
isolated mass in nonlymphoid tissues such as the eye or nervous
system. If the
immunophenotype is of T-cell origin it may denote a poorer clinical
prognosis.
 |
| Figure
1. Thymic lymphoma in a feline leukemia virus-infected
cat. The mass of neoplastic lymphocytes occupies most of
the thoracic
cavity and displaces the heart and lungs (image courtesy
of Noah’s Arkive, the University of Georgia). |
- Lymphocytic leukemia may occur independently
of or in conjunction with malignant lymphoma.
- Erythroid and myeloid leukemias, including
myeloproliferative disorders, are the most common hematologic malignancies
in cats.
- Fibrosarcoma is caused by a defective mutant
of FeLV designated feline sarcoma virus or FSV. In some cats, FeLV
lacks the viral machinery to replicate and may use the FSV retrovirus
as a helper virus to initiate viral replication.
- Myelodysplastic
syndrome (Fig. 2) is characterized
by anemia, leukopenia, and/or thrombocytopenia. This is
a frequent outcome, especially from infection with FeLV subtype
C, as many anemic
cats display a normochromic, normocytic or macrocytic non-regenerative
anemia. Macrocytosis may represent skipped mitosis of the
RBCs in the presence of a normocellular to hypocellular bone
marrow. The concentration
of erythropoietin is usually high, but erythropoiesis is
suppressed because FeLV kills stem cells and precursors of myeloid
and erythroid
cells. Although FeLV may not be detected in the bone marrow,
it is speculated that 30% of affected cats can attribute their
anemia to
this retrovirus. Anemias are characterized as regenerative
or nonregenerative. The presence of nucleated RBCs alone (unaccompanied
by polychromasia)
is not a sign of erythroid egeneration in a viremic cat.
Regenerative anemia secondary to extravascular hemolysis may
occur in viremic cats
with other disorders such as Mycoplasma haemofelis (Hemobartonella
felis) infection or immune-mediated hemolytic anemia. M.
haemofelis infection
may occur secondary to FeLV infections, probably as a result
of immunosuppression. A transient anemia of chronic disease
also may be present. Cats that
have pure red cell aplasia lack erythroid precursors within
the bone marrow and suggests infection with FeLV subtype
C. This viral subtype
also has been associated with medullary osteosclerosis
wherein viral infection of osteocytes and osteoblasts is
associated with defective
bone resorption and remodeling, resulting in excessive
trabeculae within the marrow cavity.
 |
| Figure
2. Bone marrow aspirate from a cat with myeloproliferative
disease. Mild dyserythropoiesis is present (Wright stain;
image courtesy of Noah’s Arkive, the University of Georgia). |
The leukocyte count may be increased, normal, or decreased in FeLV-infected
cats. If myelosuppression is present, neutropenia usually is present.
The total numbers of CD4+ and CD8+ T lymphocytes also may be decreased.
The pathogenesis is uncertain, but is thought to be immune-mediated.
Studies on the bone marrow have shown that the total colony forming
units - granulocyte-macrophage (CFU-GM) are normal, but arrested at
the metamyelocyte stage of development.
FeLV also infects megakaryocytes and platelets. Thrombocytopenia,
if present, is due to viral damage to megakaryocytes or platelets.
- Immunosuppression occurs commonly in FeLV-positive
cats. Both T and B lymphocytes are decreased, which predisposes cats
to secondary pathogens (often affecting the respiratory system). Neutropenia,
if present, also predisposes affected cats to secondary infections.
The presence of FeLV /FIV co-infection probably intensifies the immunosuppression
and also increases the possibility of lymphoma.
- Enteropathy may develop from viral infection
intestinal crypt epithelial cells. This manifestation of FeLV infection
may mimic feline panleukopenia.
- Infertility,
fetal resorption or abortion (Fig. 3) may
occur with FeLV infection. FeLV also is a cause of
the "fading
kitten" syndrome or neonatal death.
 |
| Figure
3. Neonatal deaths associated with feline leukemia virus
infection (image courtesy of Noah’s Arkive, the University
of Georgia). |
Laboratory Diagnosis of FeLV Infection
IFA and/or ELISA tests detect FeLV p27 protein. The p27 protein is
one of several core proteins that are products of the gag gene.
The IFA test may detect p27 in neutrophils and platelets from blood
or bone marrow. The ELISA test detects p27 in whole blood, plasma,
serum, saliva, or tears. Serum is the fluid of choice for ELISA testing
because saliva and tears may not contain sufficient p27 for viral detection.
Antibody titers to FeLV envelope antigens and FOCMA antibodies may
be used for diagnostic purposes, but are of little clinical relevance.
There are 6 stages of FeLV infection as follows:
- Stages 1-3 - FeLV is disseminated through the lymphoid tissue.
- Stage 4 – FeLV
infects the bone marrow.
- Stage 5 - Viral-infected neutrophils and platelets are released
from the bone marrow.
- Stage 6 – FeLV
appears in epithelial tissues (e.g.,
salivary glandular epithelium).
ELISA testing can detect p27 at stages 2-6, while IFA detects FeLV
at stages 5-6. Therefore, ELISA testing is the first diagnostic assay
to detect a positive result. Cats seropositive following ELISA testing
should be evaluated by IFA or retested by ELISA 4-6 weeks later. Some
seropositive cats can revert to a negative status due to the latency
of the virus in the bone marrow. However, the presence of FeLV can
still be detected by virus isolation to prove latency. IFA-positive
cats correlate with viremia as a positive IFA will always be ELISA
positive. Cats that are ELISA positive but IFA negative are called
discordant, meaning that there is either a false positive ELISA, false
negative IFA, or the virus is yet not in stages 5-6 of infection. The
most specific way to identify latent infections is by viral isolation
or PCR amplification of FeLV sequences from cells of the bone marrow.
Gross pathological findings depend on the type of disease that occurs.
Bone marrow hypercellularity often accompanies leukemias. Lymphoplasmacytic
infiltrates of the gingiva, lymph nodes, spleen, kidney, and liver
may be seen. Intestinal lesions similar to those seen in feline panleukopenia
may occur with enteric FeLV infection. These gross changes include
an edematous, turgid small intestine with petechial to ecchymotic hemorrhages
on the serosal and/or mucosal surfaces of the jejunum and ileum.
Treatment
| Note:
Treatment of animals should only be performed by a licensed
veterinarian. Veterinarians should consult the current literature
and current pharmacological formularies before initiating any
treatment protocol. |
Treatment will vary depending on the subset of diseases caused by
FeLV infection. Each will be discussed briefly as a separate entity.
Lymphoma- Chemotherapy is used most commonly for
cats with lymphoma, whether or not the cat has FeLV infection. Most
cats that are not treated for lymphoma will die within 2 months of
diagnosis. The staging of lymphoma may be difficult, because most cats
with this neoplasm have the alimentary form. There are specific protocols
for chemotherapy including the COP protocol which includes administration
of cyclophosphamide, vincristine, and prednisone. Doxorubicin can be
added as it is specific for lymphoma. Monitoring CBC is essential to
detect adverse reactions such as myelosuppression. The median survival
time of cats following treatment for lymphoma is approximately 10 to
12 months.
Bone Marrow Suppression/Myelodysplastic Disease-
Blood transfusions are often necessary to normalize the PCV. Even though
endogenous erythropoietin concentration is high in affected cats with
non-regenerative anemia, it has been shown that administration of recombinant
erythropoietin can help increase the PCV. Iron supplementation usually
is not indicated unless a source of chronic hemorrhage is identified.
FeLV-
Unfortunately, human antiviral drugs have little to no effect in
clearing this virus. AZT (3’-azido-3’-deoxythymidine)
can prevent viremia if given early after inoculation of FeLV. Experimental
studies have shown that antiviral drugs may decrease antigenemia, but
also may cause myelosuppression. Interferon alpha 2-b, administered
along with AZT, may decrease the antigenemia. Unfortunately, these
drugs may trigger an antibody response that decreases the efficacy
of these antiviral drugs to ~7 weeks duration. Staphylococcal protein
A (SPA) also has been used in the therapy of FeLV infection. SPA binds
the Fc portion of IgG. Experimental studies have demonstrated decreased
viremia and remission of lymphoma in some cats. SPA has also been used
to treat hemolytic anemia that has been associated with FeLV infection
in some cats.
Prevention of FeLV Infection
Current commercial vaccines include a killed virus with adjuvant,
killed virus without adjuvant, or a recombinant gp70 protein vaccine
with an adjuvant. Administration of these vaccines does not interfere
with FeLV testing via IFA or ELISA. A potential adverse consequence
of FeLV vaccination inludes the development of injection site-sarcomas.
It has been speculated that the adjuvant predisposes to the development
of these highly invasive tumors. Currently, the recommended site for
FeLV vaccination is on the left rear thigh or tail. If a sarcoma subsequently
develops, the location will be more amenable to surgical excision.
Before vaccinating cats against FeLV, owners should consider the risks
of FeLV exposure versus the potential of vaccine-related complications.
Living with a FeLV-Positive Cat
Many FeLV-positive cats have a good quality of life. Seropositive
cats must be kept indoors so they will not be able to transmit the
virus to other cats. If other negative cats are housed together with
a FeLV-positive cat, there is a 10-15% chance of acquiring viral infection.
Because FeLV infection may be immunosuppressive or cause tumor development,
infected cats should be monitored carefully for weakness, lymph node
enlargement, labored breathing, or other potential signs of disease.
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Acknowledgement
The copyrighted
watercolor image "Cat - Lovely on Linen" by Edie Schneider
is from her website Designs
by Edie and is used with permission. |