med chem of antifungals

Question 1

overview of fungi

Answer 1

Diverse group of eukaryotes** (> 1.5 million species): rigid cell wall, require organic compounds for both carbon and energy sources, obtain nutrients by absorption, live off decaying matter (saprophytes) or living matter (parasites)
Generally harmless for humans: relatively few are human pathogens (100’s), Most cannot infect humans with normal immune system
Two broad groups:
-Yeast
-Mold (mould)

Question 2

increasing fungal infections

Answer 2

Parallels increase in number of people who:
-Have immunosuppressive infections
-Are taking immunosuppressive drugs
-Use implanted medical devices
Four species account for ~90% of deaths: Cryptococcus, Candida, Aspergillus, Pneumocystis

Question 3

two broad groups of fungi

Answer 3

Yeast: Grow as single cells, Divide asexually by budding (fission)
Mold: Filamentous multicellular aggregates (hyphae), Hyphae grow by elongation at their tips, Usually separated into cell-like units by crosswalls called septa

Question 4

dimorphic fungi

Answer 4

Grow as hyphae at room temperature
Grow as yeast in human tissue or on media at 37 C
Conversion to yeast form appears to be necessary for pathogenesis

Question 5

characteristics of pathogenic fungi

Answer 5

Able to grow at high temperatures
Able to reach target tissues
-Dissemination in air (spores or similar)
-Penetration of host barriers
-Dissemination in body -Ability to change morphology is key, Many fungal pathogens are thermally dimorphic
Able to digest and absorb components of human tissues
Able to withstand/evade immune system

Question 6

sporulation

Answer 6

Reproduction and spread in the environment

Source of infection

Question 7

classification of fungal infections

Answer 7

True vs opportunistic
-True: cutaneous infective, subQ infective or systemic infective
Superficial and cutaneous - diseases are generally cosmetic, not life-threatening
Subcutaneous - fungi are generally implanted in skin, fungal growth produces a lesion
Systemic or invasive - Fungi have invaded the deep tissues, Can be self limiting or cause severe disease with high mortality rates

Question 8

superficial and cutaneous infections

Answer 8

Dermatophytosis
-Classic skin and hair infections (ringworm, athlete’s foot, jock itch, etc.)
-Involve 3 genera of mold that grow on keratin on a living host (Epidermophyton, Trichophyton, and Microsporum)
-Cause a series of conditions referred to as tineas
—Tinea capitis = ringworm of the scalp
—Tinea pedis = athlete’s foot
Onchomycosis
-refers to non-dermatophyte nail infections or to any fungal nail infection caused by any fungus

Question 9

systemic invasive infections

Answer 9

Examples: Coccidioides, Histoplasma, Blastomyces
Usually begin in lung – asymptomatic, influenza- like, or pneumonia
May disseminate to internal tissues or organs
-Blastomyces – bone, skin, joints
-Histoplasma – gastrointestinal tract, adrenals, bone and skin
Usually asymptomatic and self limiting, but may be severe and life threatening
Immune response is cell mediated
Infection is not communicable
Geographically restricted (endemic fungi)

Question 10

histoplasmosis

Answer 10

Caused by dimorphic endemic fungi** Histoplasma capsulatum var. capsulatum
Bat or bird droppings
Spores!
Lung is most frequent site of infection
All stages of this disease may mimic tuberculosis
People at risk for disseminated disease 
-Immunosuppressed individuals
-children under 2 years old
-elderly

Question 11

blastomycosis

Answer 11

Caused by Blastomyces dermatitidis
-Endemic dimorphic fungi
-survives in soil that contains organic debris (rotting wood, animal droppings, plant material)
-infects people collecting firewood, tearing down old buildings, etc.
1-2 cases per 100,000 in endemic areas
50% of primary infections are asymptomatic
Acute pulmonary disease indistinguishable from bacterial pneumonia
Permanent lung damage with chronic disease
Mortality rate is about 5%

Question 12

Coccidioidomycosis

Answer 12

Dimorphic fungus Coccidioides immitis
Endemic** in southwest US
Infection begins in lungs after inhaling spores
50% of infections are asymptomatic
Symptoms are flu-like
Severe pulmonary disease may develop in HIV-infected persons

Question 13

Opportunistic fungal infections

Answer 13

Not considered true pathogens - do not cause disease in immunocompetent people; low virulence
Most common: Candida, Cryptococcus, Pneumocyctis, Aspergillus, Mucomorales
Risk factors: immunosuppression, major burn wounds or trauma, central venous catheters, broad-spectrum antibiotics, Diabetes, renal insufficiency requiring dialysis

Question 14

Candidiasis

Answer 14

Caused by Candida albicans and other species of Candida
Classified as a yeast
Part of the normal human flora
Occurs when: members of the normal flora are suppressed, host immune response is diminished, especially neutrophil function
Can be localized to mucous membrane or may be invasive
-Candidemia – blood stream infection
-visceral infections

Question 15

scope of the problem

Answer 15

Most common fungal pathogens - 8 cases per 100,000 in the general population
75% of women have at least one bout of vulvovaginal candidiasis (VVC)
> 90% of people infected with HIV who are not receiving therapy develop oropharyngeal candidiasis
4th most common bloodstream infection among hospitalized patients in the U.S.

Question 16

diseases caused by candida

Answer 16

Can infect healthy and immunocompromised people
Cutaneous candidiasis
-diaper rash, jock itch, athlete’s foot
-key factor: prolonged exposure of normally dry skin to moisture
Esophagitis - HIV patients
Onchomycosis (nail)
Oropharyngeal (thrush)
Vulvovaginitis: Women treated with broad-spectrum antibiotics, Pregnancy, Diabetes
Candidemia and invasive (Systemic) infections
-Not typically diseases of healthy individuals
-Can involve virtually any organ
-Mortality ranges from 30-40%
-Responsible for the largest number of deaths from fungal infections
Most Candida infections are mucocutaneous and do not cause mortality

Question 17

aspergillosis

Answer 17

Large spectrum of diseases caused by many species of Aspergillus
Hyphal growth
Three disease states:
-Opportunistic infections (inhaled into the respiratory tract, characterized by angioinvasion, hemorrhage and tissue infarction, especially in the lungs)
-Allergic states
-Toxicoses** - some species produce toxins (aflatoxin)
Risk factors
-Prolonged granulocytopenia & organ transplant
-Not HIV
High mortality rate

Question 18

Cryptococcosis

Answer 18

Most cases caused by Cryptococcus neoformans
-Exists only as a yeast
-Found in soil worldwide - usually with bird droppings (especially pigeons)
-Cryptococcus gattii outbreak in NW
Wide polysaccharide capsule*
Acquired by inhalation
Presents most commonly as chronic meningitis
85% of cases occur in HIV-infected persons (2-7 cases per 1000 AIDS patients)
12 % fatality rate in AIDS patients

Question 19

antifungal drugs: polyenes

Answer 19

i.e. amphotericin B
Main features
-natural product - produced by Streptomyces nodus
-Amphoteric - has both an acidic and basic groups
-Contains a lipophilic polyene region (bottom) and a hydrophilic polyalcohol region (top) - amphiphilic
-Macrolide ring
-Fungicidal

Question 20

amphotericin B MOA

Answer 20

Amphotericin B binds to ergosterol in cell membrane - predominant sterol in fungal cell membranes - leakage of intracellular cations and proteins
Reason for specificity: mammalian and bacterial cell membranes contain cholesterol

Question 21

amphotericin B - PKs

Answer 21

Poorly absorbed from GI tract
Oral amphotericin B only effective for GI infections
Intravenous injection required for systemic infection
Cerebrospinal levels 2-3% of blood levels
-intrathecal therapy needed for fungal meningitis

Question 22

amphotericin B AEs

Answer 22

Toxicity is low enough to allow use, but still very toxic
Infusion-related
-Fever, chills, muscle spasms, vomiting, headache and hypotension
-Can be ameliorated by reducing rate of infusion
-Premedication with diphenhydramine and/or acetaminophen
Renal damage
-Occurs in nearly all patients
-Reversible component - reduced renal perfusion
-Irreversible component - renal tubular injury - Usually occurs after prolonged (>4 g) administration
Liver abnormalities occasionally observed

Question 23

therapeutic applications

Answer 23

Systemic infections
-Amphotericin B
—broad spectrum antimycotic (Candida albicans, Cryptococcus neoformans, Histoplasma capsulatum, Blastomyces dermatitidis, Coccidioides immitis, and Aspergillus fumigatus)
—Some fungi are naturally resistant
—Drug of choice for life-threatening fungal infections
-Intravenous administration over 1-4 hours
• Superficial fungal infections
-Nystatin - polyene drug similar to amphotericin B
—Too toxic for systemic administration

Question 24

amphotericin formulations

Answer 24

Conventional amphotericin B (C-AMB; Fungizone™)
-Available since 1960
-Colloidal suspension
-Deoxycholate (a bile salt) used as the solubilizing agent
Lipid formulations
-Amphotericin B colloidal dispersion (ABCD; Amphotec™)
-Liposomal amphotericin B (L-AMB; Ambisome™)
-Amphotericin B Lipid Complex (ABLC; Abelcet™)

Question 25

lipid formulations of amphotericin

Answer 25

Lipid formulations reduce nephrotoxicity
Act as reservoir of amphotericin
-Lipids have intermediate affinity for amphotericin - higher than cholesterol, but lower than ergosterol
Formulations use different lipids
Ambisome also reduces infusion toxicity
-Only AmBisome uses true liposomes
ABCD has less neprotoxicity but potentially more fever
COST!!

Question 26

ergosterol synthesis pathway

Answer 26

Most fungi have ergosterol in their cell membranes
Plays same role as cholesterol in mammalian cell membranes
-Very similar pathways for synthesis

Question 27

antifungal drugs: allyamines

Answer 27

terbinafine
Mode of action: disrupts ergosterol synthesis
Mechanism of action: inhibits squalene epoxidase

Question 28

antifungal drugs: terbinafine

Answer 28

Fungicidal - Death results from accumulation of squalene, not loss of ergosterol
2,500 fold selectivity for fungal enzyme compared to mammalian enzyme
Mainly effective against dermatophytes, especially onchomycoses
-More effective, less toxic, & requires shorter treatment than griseofulvin
Available for oral and topical administration
-ringworm, pityriasis versicolor, and fungal nail infections
-Lamisil (and several other brand names)
Tolnaftate (Tinactin), butenafine (Lotrimin Ultra), and naftifine (Lotrimin) are chemically similar
Same mechanism
Only available in topical preparations
Butenafine has superior efficacy against dermatophytes, Candida, Cryptococcus, Aspergillus
-Also has anti-inflammatory properties

Question 29

antifungal drugs: azoles

Answer 29

Largest class of antimycotics: >20 drugs
Key feature: 5-membered aromatic ring
Mechanism of action
-Inhibition of 14 a-demethylase
Fungistatic

Question 30

azoles MOA

Answer 30

Azoles inhibit the binding and activation of molecular oxygen by cytochrome P450 - Inhibit the conversion of lanosterol to ergosterol - create toxic sterols which accumulate in cell membrane

Question 31

azole selectivity

Answer 31

Humans use same enzyme to make cholesterol for our cell membranes
Fungal enzyme more sensitive
-Ketoconazole IC50 for Candida enzyme = 10^9 M
-Ketoconazole IC50 for human enzyme = 10^6 M
-However, azoles inhibit other mammalian cytochrome P450s

Question 32

azole metabolism

Answer 32

In general, azoles are metabolized extensively by liver cytochrome P450s
All metabolites are inactive
Only those azoles with reduced metabolism are used for systemic infection
-Ketoconazole
—First orally active azole
—Clinically important interactions with human CYP450s
-Fluconazole
-Itraconazole
-Voriconazole
-Posaconazole
-Isavuconazole

Question 33

early azole antifungals

Answer 33

Clotrimazole and miconazole were the first described azole antifungals (1969)
Differ in distance of azole group from asymetric carbon
Miconazole used as basis for later generation azoles
Alterations change
-Spectrum of activity
-Interaction with CYPs
-Route of elimination

Question 34

ketoconazole

Answer 34

First azole with sufficient oral bioavailability to be used clinically for deep tissue infections
Based on miconazole
-Dioxolane ring on asymetric carbon
-Reduced metabolism by CYP3A

Question 35

itraconazole

Answer 35

Based on ketoconazole

• Triazole instead of imidazole
• Modified substituent on dioxolane ring
• Improved specificity for fungal P450 enzyme

Question 36

Posaconazole

Answer 36

Derived from itraconazole
-Has furan ring – alters and increases spectrum of activity
-F replaces Cl
Broad spectrum activity
Available for oral (as suspension) and IV admin

Question 37

Isavuconazole

Answer 37

Structurally similar to voriconazole
Broad spectrum activity
-Similar to voriconazole, but also Zygomycetes
Water soluble prodrug
-Cyclodextrin not required for solubility
-Reduced nephrotoxicity relative to voriconazole
Long half life

Question 38

azole drugs and CYP450

Answer 38

In general, azole antifungals are metabolized by and inhibit liver CYP450 enzymes**

• Triazole concentrations can be increased by other drugs metabolized by this pathway
• Concentration of drugs metabolized by CYP enzymes can be increased
• Inducers of CYPs can decrease triazole levels - Rifampicin - potent inducer

Question 39

ketaconazole and CYP450

Answer 39

Ketoconazole is a potent inhibitor of CYP3A4
Drug interactions
-Inhibits metabolism of terfenadine (Seldane) and cisapride (both removed from US market)
-Increases area under curve and half life of triazolam
-Increases bioavailability of cyclosporin
-CYP3A4 inducers (rifampin, etc.) reduce ketoconazole levels

Question 40

azole metabolism

Answer 40

Itraconazole - extensively metabolized by CYP3A4 in liver
Fluconazole - 80 % excreted by kidney unchanged
Voriconazole - metabolized extensively in liver by CYP2C19 > CYP3A4&raquo_space; CYP2C9
-CYP2C19 polymorphisms can alter levels
Posaconazole - metabolized in liver by glucuronidation

Question 41

fluconazole clinical uses

Answer 41

High solubility, bioavailability
Penetrates CSF
Widest therapeutic index of the azoles
Spectrum of activity
-Good activity against C. albicans and many other Candida species - Most commonly used agent for mucocutaneous Candida
-Some Candida species are naturally resistant (C. krusei, C. glabrata)
-Cryptococcus neoformans - Azole of choice for treatment and prophylaxis of cryptococcal meningitis
-No therapeutically useful activity against histoplasmosis, blastomycosis, or sporotrichosis
-No activity against Aspergillus or filamentous fungi

Question 42

Itraconazole clinical uses

Answer 42

Similar spectrum to fluconazole, plus aspergillus
-Not as broad as voriconazole, posaconazole, or isavuconazole
Azole of choice for Histoplasma, Blastomyces, and Sporothrix
Extensively used for dermaphytoses and onchomycoses
Variable absorption
Bad taste

Question 43

Voriconazole clinical uses

Answer 43

Highly soluble
High oral bioavailability
CSF levels ~1/2 of plasma levels
Active against Candida species, including some fluconazole-resistant strains
Extended spectrum of activity against yeasts, Cryptococcus and molds, including Aspergillus
Active against some fluconazole-resistant Candida spp.
May be more effective against Aspergillus than amphotericin B
Teratogenic in animals and is contraindicated in pregnancy (Category D)
Visual disturbances in 30% of patients - Flickering lights or zigzag lines

Question 44

Posaconazole clinical uses

Answer 44

Approved in May 2007
Broadest spectrum azole to date
Spectrum of activity similar to voriconazole - Better activity against filamentous fungi such as zygomycetes

Question 45

Isavuconazole clinical uses

Answer 45

Spectrum of activity similar to voriconazole
Approved for treatment of invasive aspergillosis and mucormycosis
water-soluble intravenous formulation
oral formulation has high bioavailability
few serious adverse effects
fewer drug–drug interactions than voriconazole

Question 46

topical azoles for superficial fungal infections

Answer 46

Clotrimazole and miconazole most common
Ketoconazole available as shampoo
Newest topical azoles
-Luliconazole
-Efiniconazole – First topical treatment for onychomycosis - as effective as oral itraconazole

Question 47

antifungal drugs: Echinocandins

Answer 47

Second newest class of antifungals
Lipopeptides**
-Synthetically modified fungal compounds
-Caspofungin - Glarea lozoyenisi
-Micafungin - Coleophoma empedri
-Anidulafungin - Aspergillus nidulans
All must be administered by IV
Cyclic hexapeptides with long, modified fatty acid side chains

Question 48

echinocandins

Answer 48

Inhibit synthesis of b(1-3)glucan - cell wall component – inhibits
-b(1-3) glucan synthase is the target enzyme
Reason for selectivity
-Mammalian cells lack this activity
Fungicidal
Broad spectrum activity
-Synergistic with voriconazole and amphotericin B
No cross resistance with other antifungals

Question 49

echinocandins - clinical uses

Answer 49

Caspofungin
-Disseminated and mucocutaneous candida
-Salvage therapy in patients with aspergillosis who fail to respond to amphotericin B
Micafungin
-mucocutaneous candida
-Candida prophylaxis in bone marrow transplant patients
Anidulafungin
-Esophogeal candidiasis
-Invasive candidiasis
-Has longest half life and no known drug interactions
Micafungin and anidulafungin are associated with fewer adverse events

Question 50

echinocandins metabolism

Answer 50

NOT metabolized by liver CYPs
-Anidulafungin and micafungin generally have fewer adverse effects
Degraded in blood and in tissues
-Ring opening
-Peptide hydrolysis

Question 51

antifungal drugs: flucytosine

Answer 51

Mode of action: antimetabolite
Mechanism:
-Inhibits thymidylate synthase
-Interferes with protein synthesis
Reason for specificity: mammalian cells are unable to convert flucytosine to active metabolite
Synergizes with amphotericin B

Question 52

flucytosine MOA

Answer 52

Flucytosine is first converted by cytosine deaminase to 5-fluorouracil (5-FU)
phosphorylated to form 5-FdUMP
5-FdUMP mimics dUMP
5-FdUMP is a substrate, a competitive inhibitor, and a suicide inhibitor of thymidylate synthase
In 5-FdUMP, there is an F in place of H found in dUMP
F is the most electronegative atom -> cannot be eliminated
TS trapped in an inactive form and cannot react with dUMP
No dTMP can be produced, and this inhibits DNA synthesis

Question 53

flucytosine PKs

Answer 53

Available only in oral form
Penetrates well into all fluid compartments including cerebrospinal fluid
Removed by kidney
Renal impairment can lead to toxicity

Question 54

flucytosine AEs

Answer 54

Intestinal flora can metabolize to 5-FU - anti cancer drug

Monitor levels when combined with amphotericin B (why?)

Question 55

flucytosine clinical uses

Answer 55

Limited spectrum of activity
-Cryptococcus neoformans
—Combined with amphotericin B for crytococcal meningitis
-Some Candida species
-Aspergillus
-Most filamentous fungi are not susceptible to 5-FC
Narrow therapeutic window
-Concentration too high - toxicity
-Concentration too low - resistance
Nearly always administered with amphotericin B or fluconazole

Question 56

antifungal drugs: griseofulvin

Answer 56

Discovered in 1939
Produced by a strain of Penicillium
Disrupts fungal microtubules
Fungistatic
Must be given orally - Becomes incorporated in keratin precursor cells
Used for dermatophytes
Inactive against yeast, mold, and dimorphic fungi - not absorbed

Question 57

Tavaborole

Answer 57

Newest class of antifungal drugs
Mechanism – inhibits leucyl transfer RNA synthetase (LeuRS)
-Inhibits protein synthesis
Boron is essential for activity
Topical treatment of onychomycosis

Question 58

Resistance to antifungal agents

Answer 58

Natural resistance (intrinsic) vs. induced (acquired)
Candida krusei - intrinsically resistant to fluconazole; reduced susceptibility to flucytosine and amphotericin B
Candida glabrata - multiazole, echinocandin, and multidrug resistance
-constitutive expression of drug resistance pathways
Aspergillus terreus - intrinsically resistant to amphotericin
Antifungal treatment has altered the types of fungi associated with infection
-C. glabrata is 2nd most commonly isolated Candida species

Question 59

Resistance to antifungal agents

Answer 59

Natural resistance (intrinsic) vs. induced (acquired)
Candida krusei - intrinsically resistant to fluconazole; reduced susceptibility to flucytosine and amphotericin B
Candida glabrata - multiazole, echinocandin, and multidrug resistance
-constitutive expression of drug resistance pathways
Aspergillus terreus - intrinsically resistant to amphotericin
Antifungal treatment has altered the types of fungi associated with infection
-C. glabrata is 2nd most commonly isolated Candida species
Acquired resistance not transferred between strains as in bacteria
Azoles
-Target site alteration – accounts for most resistant strains
-Reduced drug concentration via efflux pumps
-Target enzyme upregulation
-Development of bypass pathways
-Increasingly common, esp. Aspergillus
Polyenes - reduced ergosterol content
Echinocandins - target site mutations; rare
Flucytosine - cytosine deaminase or UPRT (cytosine permease)
Allylamines and griseofulvin - not well characterized